{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"设计并制备了以不同橡胶为基体、具有不同界面结合强度的玻璃纤维芯铅丝(网)增强橡胶复合材料(GF/Pb/R),通过比较它们的动态压缩模量和阻尼损耗因子,研究了复合方式、橡胶基体性能和界面结合强度对于GF/Pb/R动态性能的影响.","authors":[{"authorName":"吕丽","id":"bffd5a4f-3289-4d36-966c-1f2795212d19","originalAuthorName":"吕丽"},{"authorName":"白书欣","id":"782c2ff5-9942-4b32-8f33-42882afce88b","originalAuthorName":"白书欣"},{"authorName":"张虹","id":"367b48c7-6476-410e-9690-0568f6d06ee6","originalAuthorName":"张虹"},{"authorName":"王进","id":"0a06e8a7-c24f-490f-9e01-6543908e8748","originalAuthorName":"王进"},{"authorName":"杨军","id":"9be1cc66-1e42-4870-9db9-90a641c0ec88","originalAuthorName":"杨军"}],"doi":"10.3969/j.issn.1007-2330.2007.02.008","fpage":"34","id":"17ef22fd-b792-4cbd-811d-e4ea98caf01d","issue":"2","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":"86e10e6a-6939-4852-a1e5-40dbb9233a6f","keyword":"玻璃纤维芯铅丝(网)","originalKeyword":"玻璃纤维芯铅丝(网)"},{"id":"a429f791-7bac-49c5-9fac-3e07861a0be8","keyword":"阻尼","originalKeyword":"阻尼"},{"id":"4030b737-a421-4e58-9b55-568e7b17d26c","keyword":"动态性能","originalKeyword":"动态性能"},{"id":"6b2dd54c-51a2-461a-ad7e-ec8fb6732a63","keyword":"橡胶复合材料","originalKeyword":"橡胶复合材料"}],"language":"zh","publisherId":"yhclgy200702008","title":"玻璃纤维芯铅丝(网)/橡胶动态性能影响因素研究","volume":"37","year":"2007"},{"abstractinfo":"本文根据材料性能互补原理,结合阻尼减振机制,设计并制备了一种(金属/无机纤维/橡胶)三元阻尼材料-玻璃纤维芯铅丝增强橡胶复合材料(GF/Pb/R).研究了具有不同界面结合强度(弱、中等、强结合)的GF/Pb/R在-30℃~50℃、5Hz和27℃、1~50Hz两种条件下的存储模量和阻尼性能.结果表明,三种复合材料的力学性能均比橡胶高,其刚度随界面结合强度提高而提高;复合材料损耗因子按照界面弱结合、强结合和中等强度结合的顺序降低,其阻尼性能随温度的变化比橡胶平缓.","authors":[{"authorName":"吕丽","id":"4e43723e-42dd-4bee-a59a-af1e5c676285","originalAuthorName":"吕丽"},{"authorName":"白书欣","id":"b87e6e11-323a-48d0-a461-9ed806507e51","originalAuthorName":"白书欣"},{"authorName":"张虹","id":"2899a271-ee6e-4c3d-96bb-29483e1950e9","originalAuthorName":"张虹"},{"authorName":"王进","id":"39e2865a-2ee2-4e72-8f97-f01c3403f565","originalAuthorName":"王进"},{"authorName":"杨军","id":"328c5cd4-4bdf-4b7d-8e97-776162fc1659","originalAuthorName":"杨军"},{"authorName":"肖加余","id":"76cab4cb-2e45-4946-ae8a-40c9a2df9fab","originalAuthorName":"肖加余"}],"doi":"10.3969/j.issn.1673-2812.2006.06.011","fpage":"843","id":"c0ca1ab5-367a-467e-91e4-446d3b502641","issue":"6","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":"5994f1fd-2cc3-425d-af2a-2d1846155379","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"338ffd4d-9fc0-489c-9a8e-89735d1e6f75","keyword":"阻尼","originalKeyword":"阻尼"},{"id":"31041512-4509-499f-8ec6-9b9152b11606","keyword":"玻璃纤维芯铅丝(GF/Pb丝)","originalKeyword":"玻璃纤维芯铅丝(GF/Pb丝)"},{"id":"b955d23e-ac79-4653-885a-f522dc5f7b3b","keyword":"动态性能","originalKeyword":"动态性能"}],"language":"zh","publisherId":"clkxygc200606011","title":"玻璃纤维芯铅丝增强橡胶复合材料阻尼性能研究","volume":"24","year":"2006"},{"abstractinfo":"制备了具有不同结构和界面结合强度的玻璃纤维芯-铅网增强橡胶复合材料(GF-Pb/R),并通过测试复合材料的力滞回线,研究了其在3~20Hz时的动态性能.结果表明,GF-Pb网增强结构可以同时提高橡胶的动态力学性能和阻尼性能,其中GF-Pb网垂向增强方式的性能改善效果明显,当GF-Pb网体积分数为4%时,其动刚度和损耗因子的提高率可分别达到49%和25%.GF-Pb/R复合材料阻尼性能是材料阻尼、界面微滑移阻尼、Pb塑性变形阻尼等多种阻尼机制共同作用的结果.界面粘结强度显著影响了复合材料的力学性能和阻尼行为: GF-Pb/R刚度随界面结合强度的增大而提高; 损耗因子按照界面中等强度结合、强结合、弱结合的顺序递增.","authors":[{"authorName":"吕丽","id":"004954a2-a9e1-41fa-976f-fd860dad2ecf","originalAuthorName":"吕丽"},{"authorName":"白书欣","id":"7b4753c4-ba33-47a1-8cef-072c36a55315","originalAuthorName":"白书欣"},{"authorName":"张虹","id":"1d3d3b88-b371-4658-ae6a-30ff7dfe47bb","originalAuthorName":"张虹"},{"authorName":"王进","id":"11a32c10-d38c-41dc-927b-4f7eda031169","originalAuthorName":"王进"},{"authorName":"肖加余","id":"13f47a19-d49a-431d-b2e7-af445b5f52e7","originalAuthorName":"肖加余"},{"authorName":"杨军","id":"26b99a2c-dcde-4e51-b31e-73072e577c83","originalAuthorName":"杨军"}],"doi":"10.3321/j.issn:1000-3851.2006.06.006","fpage":"37","id":"7c7344fe-1719-4445-abda-1a890fd21b48","issue":"6","journal":{"abbrevTitle":"FHCLXB","coverImgSrc":"journal/img/cover/FHCLXB.jpg","id":"26","issnPpub":"1000-3851","publisherId":"FHCLXB","title":"复合材料学报"},"keywords":[{"id":"32abe25a-d31a-4af0-832c-27c9c5ebf398","keyword":"橡胶复合材料","originalKeyword":"橡胶复合材料"},{"id":"58e6a875-5a2e-4e46-a2b4-9eeb49ed8d77","keyword":"动态性能","originalKeyword":"动态性能"},{"id":"f5bc4e18-7e9b-42af-aa14-9f58dc74e498","keyword":"界面","originalKeyword":"界面"},{"id":"9a685bb4-1ee0-48a8-b0a4-b9aa8a07ea79","keyword":"阻尼","originalKeyword":"阻尼"},{"id":"a230a91d-30c1-45ca-83fd-450bb0f57b81","keyword":"粘结强度","originalKeyword":"粘结强度"}],"language":"zh","publisherId":"fhclxb200606006","title":"玻璃纤维芯-铅网增强橡胶复合材料动态性能","volume":"23","year":"2006"},{"abstractinfo":"为了改善橡胶的力学性能和阻尼性能,以橡胶、纤维和铅为原料设计了玻璃纤维增强铅网/橡胶阻尼复合材料,研究了不同玻璃纤维增强铅网铺层数量的横向玻璃纤维增强铅网/橡胶复合材料力学性能和阻尼性能,分析了其阻尼机制.结果表明,复合材科具有比橡胶更高的力学性能和阻尼特性,其刚度随铅网铺层数量的增加而提高,而阻尼损耗因子与铺层数呈非线性关系.复合材料中存在材料变形耗能、界面耗能、摩擦耗能等多种阻尼损耗机制.","authors":[{"authorName":"吕丽","id":"1e0f8c13-db41-44c9-9d11-f70aa4a5e2d6","originalAuthorName":"吕丽"},{"authorName":"白书欣","id":"11f9e165-f6a5-44a8-922a-dea80c4a4ca2","originalAuthorName":"白书欣"},{"authorName":"张虹","id":"c16d7b12-3beb-4264-a3f9-802679067eea","originalAuthorName":"张虹"},{"authorName":"肖加余","id":"eb219417-7081-4c3f-94ba-ad7eda3a9840","originalAuthorName":"肖加余"}],"doi":"","fpage":"748","id":"08fb047f-bb2c-4895-aaf5-bd88fcbf9181","issue":"6","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":"51ddf1fc-5aef-49a9-8858-9d3c48057292","keyword":"阻尼","originalKeyword":"阻尼"},{"id":"5c9a86c8-bd9a-4d53-9818-74c58f72e80b","keyword":"减振","originalKeyword":"减振"},{"id":"ed164543-5a77-4721-88a6-443d7e7127b9","keyword":"振动控制","originalKeyword":"振动控制"},{"id":"5350d08e-6af8-423c-ad31-bf923f2fcec5","keyword":"粘弹材料","originalKeyword":"粘弹材料"},{"id":"46ff656a-98fe-470f-9b97-78207bd15d61","keyword":"复合材料","originalKeyword":"复合材料"}],"language":"zh","publisherId":"clkxygy200806003","title":"玻璃纤维增强铅网/橡胶阻尼复合材料研究","volume":"16","year":"2008"},{"abstractinfo":"本文主要介绍了一种高性能包芯纱.它是以高性能纤维为芯纱、热融纤维为包缠纱,通过二维编织工艺加工而成.外层编织纱对高性能芯纱的保护使复合后的纱线的织造性能得到很大改善,可直接在二维或三维织机上进行织造.织物下机后经过热压成为热塑性复合材料.本文对丙纶/玻璃纤维包芯纱的纱线设计、纱线的几何模型进行了理论研究,确立了纱线结构参数的计算方法.","authors":[{"authorName":"王荣荣","id":"321aaad9-90dc-4847-9942-6e63f7b0a860","originalAuthorName":"王荣荣"},{"authorName":"马崇启","id":"fccc28e7-6807-4a1e-aa74-e0c325b5c5ba","originalAuthorName":"马崇启"},{"authorName":"黄故","id":"bb6e7fbc-f9a6-4758-ac6c-53d4b9ac1dbb","originalAuthorName":"黄故"}],"doi":"10.3969/j.issn.1003-0999.2007.03.012","fpage":"41","id":"62a5a75f-da95-482b-9dd5-7c15a5912221","issue":"3","journal":{"abbrevTitle":"BLGFHCL","coverImgSrc":"journal/img/cover/BLGFHCL.jpg","id":"6","issnPpub":"1003-0999","publisherId":"BLGFHCL","title":"玻璃钢/复合材料"},"keywords":[{"id":"390e05b7-f655-4708-8e2d-b318e4380099","keyword":"纤维增强复合材料","originalKeyword":"纤维增强复合材料"},{"id":"ae46dc97-7ee1-4424-ae58-3f32d5e2a3a9","keyword":"高性能纤维","originalKeyword":"高性能纤维"},{"id":"690b5f1d-7224-4da8-897c-d928c891cdfe","keyword":"玻璃纤维","originalKeyword":"玻璃纤维"},{"id":"3c63d79b-b448-4c40-8ffc-a1f93c294fb5","keyword":"热融纤维","originalKeyword":"热融纤维"},{"id":"c584d739-edff-4159-bfdc-88d69d290f62","keyword":"丙纶","originalKeyword":"丙纶"},{"id":"9ac0d47b-a967-48d9-ad48-8413462910e1","keyword":"包芯纱","originalKeyword":"包芯纱"}],"language":"zh","publisherId":"blgfhcl200703012","title":"丙纶/玻璃纤维包芯纱的研制","volume":"","year":"2007"},{"abstractinfo":"对大跨度建筑用复合金属屋面板的玻璃纤维夹芯材料的力学性能进行了试验测定.测得了玻璃纤维棉层压方向和顺纹方向的拉压强度、弹性模量和泊松比等基本力学参数,结果表明层压方向和顺纹方向的力学性质不相同.采用振动梁法进行了阻尼特性试验,得到了材料损耗因子的值,并根据试验数据拟合出了玻璃纤维棉损耗因子-频率的曲线,在测试频率范围内材料的损耗因子值为0.5左右,表明该材料为高阻尼材料.进一步以一块玻璃纤维夹芯复合金属板为算例,采用模态应变能法对其阻尼特性进行了数值分析.玻璃纤维夹芯复合屋面板的各阶模态损耗因子在0.3~0.5左右,表明玻璃纤维夹芯复合金属板具有较高的结构阻尼,在大跨度结构风振计算中将玻璃纤维夹芯复合金属屋面板看作刚性板是不正确的.","authors":[{"authorName":"黄莉","id":"12f164b5-c9f9-4f41-accf-cc37ee74dba2","originalAuthorName":"黄莉"},{"authorName":"邓华","id":"c4bddacf-df01-436b-b6f5-57feb2bfcc0e","originalAuthorName":"邓华"},{"authorName":"王宸","id":"87d6cbf9-3e87-44bd-a712-f8e318e724c5","originalAuthorName":"王宸"}],"doi":"","fpage":"544","id":"a840d3a9-c58d-4c39-aff7-d02aed7cda97","issue":"4","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":"562a7cc9-3236-4335-b67e-0a3a6d09b169","keyword":"玻璃纤维棉","originalKeyword":"玻璃纤维棉"},{"id":"1a1417b9-3f60-4e2d-b480-bb6c29028f02","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"bd249bef-aa0a-4626-9960-dd8934f5a20b","keyword":"阻尼性能","originalKeyword":"阻尼性能"},{"id":"99c49098-60f7-4e95-8581-2eaedec3235e","keyword":"振动梁法","originalKeyword":"振动梁法"},{"id":"31a42e93-4666-4b80-bea2-9215d4b4e9d6","keyword":"金属复合屋面板","originalKeyword":"金属复合屋面板"},{"id":"8c4b24e4-053a-43f4-9f70-1426c889e2ab","keyword":"模态应变能法","originalKeyword":"模态应变能法"},{"id":"e8116702-97fe-4fd3-a425-263648a593ed","keyword":"结构损耗因子","originalKeyword":"结构损耗因子"}],"language":"zh","publisherId":"clkxygc201304015","title":"玻璃纤维夹芯材料力学性能与阻尼特性分析","volume":"31","year":"2013"},{"abstractinfo":"研究了在空气和含NO2气氛中不同温度下对GF/Cu皮芯复合导电纤维材料加速老化,力学性能、电学性能的影响,以及空气中高低温冲击导致其力学性能变化的规律.给出了导电纤维材料在不同环境中的氧化动力学曲线并分别计算了氧化激活能,推算出室温(25℃)条件下不同气氛中的储存氧化半衰期分别为:13.55年(空气气氛)、216.29天(氧化性气氛NO2:空气=1:1)和374.75天(氧化性气氛NO2:空气=1:2).","authors":[{"authorName":"王亚龙","id":"97dba854-14f2-465b-819d-73fcb3e61a8e","originalAuthorName":"王亚龙"},{"authorName":"陈莉云","id":"61bdda7c-ef8a-4a16-9207-409a1e6b41cd","originalAuthorName":"陈莉云"},{"authorName":"张海涛","id":"277fed85-5f04-4c84-8957-58f27e8c0db5","originalAuthorName":"张海涛"},{"authorName":"王军","id":"160318b3-7a24-439b-9a1f-241f5596b320","originalAuthorName":"王军"},{"authorName":"王旭辉","id":"8859cd93-830e-431d-9d1c-505f786d7f61","originalAuthorName":"王旭辉"},{"authorName":"张昌云","id":"a2071140-5b03-43d1-a143-74eb73ac1bd5","originalAuthorName":"张昌云"}],"doi":"10.3969/j.issn.1002-6495.2004.05.008","fpage":"291","id":"61c3c541-5846-498b-9792-743fbb1d04b3","issue":"5","journal":{"abbrevTitle":"FSXB","coverImgSrc":"journal/img/cover/腐蚀学报封面.jpg","id":"24","issnPpub":"2667-2669","publisherId":"FSXB","title":"腐蚀学报(英文)"},"keywords":[{"id":"5489f6d0-e999-493a-84c8-e2f6d1dcb933","keyword":"导电纤维","originalKeyword":"导电纤维"},{"id":"1c31b848-cf82-42d8-9fe2-9d4826831d73","keyword":"抗张强度","originalKeyword":"抗张强度"},{"id":"2aefa0b2-9b92-4ed5-a40d-c879f6d321f1","keyword":"电阻率","originalKeyword":"电阻率"},{"id":"2ee844f4-80ef-4e60-bca4-dc2bd8d8b83d","keyword":"氧化半衰期","originalKeyword":"氧化半衰期"},{"id":"96568c22-2ffc-4cb1-9c65-018181ab729d","keyword":"氧化动力学","originalKeyword":"氧化动力学"}],"language":"zh","publisherId":"fskxyfhjs200405008","title":"玻璃纤维/铜皮芯复合导电纤维老化性能研究","volume":"16","year":"2004"},{"abstractinfo":"采用改性双马来酰亚胺预聚体对酸酐/环氧树脂体系进行了耐高温化改性,制得一种耐高温玻璃钢拉挤芯棒用树脂基体配方.应用示差扫描量热、差动热分析和傅里叶红外光谱等对该改性环氧树脂体系的固化反应进行了研究,对该树脂基体固化物和其玻璃纤维增强的拉挤芯棒的力学、电气和耐热性能也进行了研究.结果表明,该树脂基体满足拉挤工艺要求,其性能达到技术指标要求.","authors":[{"authorName":"陈平","id":"530cde89-3c95-4e7b-9006-3d734cede5b0","originalAuthorName":"陈平"},{"authorName":"韩冰","id":"880c5599-86b9-4993-a0fd-bdee491610c2","originalAuthorName":"韩冰"},{"authorName":"程子霞","id":"f32e4827-04fd-4c40-9f03-4610fc3de547","originalAuthorName":"程子霞"}],"doi":"10.3321/j.issn:1000-3851.2000.02.003","fpage":"12","id":"3b9bc6cf-ae62-48fc-90d6-5278fed9a668","issue":"2","journal":{"abbrevTitle":"FHCLXB","coverImgSrc":"journal/img/cover/FHCLXB.jpg","id":"26","issnPpub":"1000-3851","publisherId":"FHCLXB","title":"复合材料学报"},"keywords":[{"id":"6d11f446-e5f7-444f-b6aa-19e25b512545","keyword":"双马来酰亚胺预聚体","originalKeyword":"双马来酰亚胺预聚体"},{"id":"c9f854e9-8f32-4f0c-a23a-5f18a8322bdb","keyword":"改性环氧树脂","originalKeyword":"改性环氧树脂"},{"id":"0509ceaa-fb02-4efc-9cc5-93c02f8b9022","keyword":"耐高温复合材料","originalKeyword":"耐高温复合材料"},{"id":"6299fcce-2eea-4bed-ae0e-a3763791c948","keyword":"固化反应","originalKeyword":"固化反应"},{"id":"1d561b9c-db15-45bf-9224-98df9cbd9e06","keyword":"性能","originalKeyword":"性能"}],"language":"zh","publisherId":"fhclxb200002003","title":"玻璃纤维增强耐高温改性环氧基拉挤电绝缘芯棒的研究","volume":"17","year":"2000"},{"abstractinfo":"采用酸浸析法,研制出平均孔径(直径)小于2nm的微孔玻璃纤维。研究了原始玻璃组分、分相处理条件等工艺参数对微孔玻璃纤维平均孔径、比表面积的影响。实验结果表明,随着原始玻璃组分中酸可溶物含量的增加,酸沥后多孔体积和比表面积增大,同样,提高分相处理温度和时间也能够提高微孔玻璃的空隙率。还研制出中空硼硅酸盐等玻璃纤维,并采用酸浸析法制备了中空微孔玻璃纤维,与微孔玻璃纤维相比,中空微孔玻璃纤维具有更高的比表面积和孔隙体积。","authors":[{"authorName":"祖群","id":"9bcbfefb-004c-49f3-98de-9cc44730b0af","originalAuthorName":"祖群"},{"authorName":"梁中全","id":"f06ed6d9-1ee4-4375-b49f-c47bfc45cd84","originalAuthorName":"梁中全"},{"authorName":"戴尚芹","id":"d7d0d4b5-d872-4640-93fb-939becb5e6be","originalAuthorName":"戴尚芹"},{"authorName":"姚正庆","id":"2084d930-613f-4e82-8daa-4a32384f4987","originalAuthorName":"姚正庆"}],"doi":"10.3969/j.issn.1001-1625.2001.03.004","fpage":"23","id":"a561ed59-a437-45f9-b1eb-244a09bf9a80","issue":"3","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"278909e1-ff74-4f8d-bb7f-427364d5d9b8","keyword":"微孔玻璃纤维","originalKeyword":"微孔玻璃纤维"},{"id":"f6a1518b-0ef8-4515-aed8-64155079f9b5","keyword":"中空微孔玻璃纤维","originalKeyword":"中空微孔玻璃纤维"}],"language":"zh","publisherId":"gsytb200103004","title":"微孔玻璃纤维的研制","volume":"20","year":"2001"},{"abstractinfo":"镀银玻璃纤维有抗电磁辐射、抗静电、消毒杀菌、反射雷达波等优异性能.玻璃纤维化学镀银法具有工艺简单、所得镀层均匀且结合力强等优点,近年来引起了人们较多的关注.本文介绍了玻璃纤维上化学镀银的方法和应用背景,详细探讨了玻璃纤维化学镀银的影响因素,并针对目前玻璃纤维化学镀银存在的一些问题提出了建议.","authors":[{"authorName":"李芝华","id":"440fcfb4-17ce-4e70-9bd5-cb53b3f4eae6","originalAuthorName":"李芝华"},{"authorName":"曹鼎","id":"29f96350-abc6-4c27-ab9d-935919f11548","originalAuthorName":"曹鼎"},{"authorName":"孙健","id":"cab2280e-3d92-46f3-8539-34b9fc952450","originalAuthorName":"孙健"}],"doi":"","fpage":"748","id":"6a0901c5-679c-4feb-8caa-6148d8acc0c8","issue":"4","journal":{"abbrevTitle":"XYJSCLYGC","coverImgSrc":"journal/img/cover/XYJSCLYGC.jpg","id":"69","issnPpub":"1002-185X","publisherId":"XYJSCLYGC","title":"稀有金属材料与工程"},"keywords":[{"id":"83029713-db51-4e13-99fa-c48bdd85b00d","keyword":"化学镀银","originalKeyword":"化学镀银"},{"id":"e37de0da-96a6-4fda-9103-60d5226f7af8","keyword":"玻璃纤维","originalKeyword":"玻璃纤维"},{"id":"11d2df13-184b-4403-83cc-1472b919f0ca","keyword":"影响因素","originalKeyword":"影响因素"}],"language":"zh","publisherId":"xyjsclygc200904041","title":"化学镀银玻璃纤维","volume":"38","year":"2009"}],"totalpage":1909,"totalrecord":19081}