{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"基于等效刚度的思想,通过设定层合板的属性参数模拟了加筋板结构的力学特性,提出了一种适用于不同截面形状以及布局形式的加筋板总体失稳分析的等效层合板建模方法.利用PATRAN/NASTRAN软件比较了反映实际壁板形状的高精度有限元模型与对应的赋有层合板属性的等效刚度简化模型.对于工程中常见形状的加强筋以及不同布局形式的壁板,2种模型的一阶线性失稳因子基本一致,从而验证了将等效层合板模型用于加筋壁板结构的稳定性分析可以满足工程精度要求,并显著提高了计算效率.","authors":[{"authorName":"赵群","id":"dd239879-d569-46b6-923b-432125e4bbbe","originalAuthorName":"赵群"},{"authorName":"金海波","id":"ba4a1af1-501f-4b9e-bfd3-a4e45d40f005","originalAuthorName":"金海波"},{"authorName":"丁运亮","id":"e8b8becb-92b7-47f1-b08b-a31e49131dd5","originalAuthorName":"丁运亮"},{"authorName":"迟鹏","id":"249ada03-a41d-4b0b-81b7-c3a02a187e3a","originalAuthorName":"迟鹏"}],"doi":"","fpage":"195","id":"9a564147-f43c-4780-92b4-faa213f018c7","issue":"3","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":"e30c123c-cefa-4652-97e5-628ad89b9418","keyword":"等效刚度","originalKeyword":"等效刚度"},{"id":"62a52ab3-2833-4698-8bdc-183068cef3fe","keyword":"加筋板","originalKeyword":"加筋板"},{"id":"6c27ab8f-b7d9-4d53-9767-e78f8b81a4e6","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"65de992a-7c60-4916-b0e7-84770fe2365a","keyword":"层合板","originalKeyword":"层合板"},{"id":"177392ef-6761-4f31-a055-333bf077fb95","keyword":"屈曲","originalKeyword":"屈曲"},{"id":"b866fca8-86e3-4ee6-8c57-16dea5d9e9ca","keyword":"有限元","originalKeyword":"有限元"}],"language":"zh","publisherId":"fhclxb200903033","title":"加筋板总体失稳分析的等效层合板模型","volume":"26","year":"2009"},{"abstractinfo":"通过试验获取了碳纤维(CF)、凯夫拉纤维(KF)、玻璃纤维(GF)、超高分子量聚乙烯纤维(UHMPEF)复合材料的力学性能和声学性能参数,在此基础上分别利用等效刚度法和传递矩阵法,对CF/UHMPEF、CF/KF、CF/GF混杂纤维复合材料的拉伸刚度、声反射系数和声透射系数进行计算.结果表明,材料的刚度和强度基本相同的条件下CF/UHMPEF复合材料声压反射系数最小,其次是CF/KF复合材料,再次是CF/GF复合材料.10kHz频率范围内3种混杂材料的声透射系数都达到95%以上.","authors":[{"authorName":"石勇","id":"03d7d636-9207-4d27-b326-2fff120c1ee8","originalAuthorName":"石勇"},{"authorName":"朱锡","id":"0ddfd87d-b244-44f3-b99c-2b97e649850d","originalAuthorName":"朱锡"},{"authorName":"李海涛","id":"91ad5713-2082-4707-b226-2933d7adfda4","originalAuthorName":"李海涛"},{"authorName":"李永清","id":"88a07f77-6e56-4aa4-9a5d-5e318ae650e7","originalAuthorName":"李永清"}],"doi":"10.3969/j.issn.1003-0999.2006.04.006","fpage":"23","id":"ae4020ad-81bc-4f5b-a890-f36dade9d4b2","issue":"4","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":"0b5cb605-d79d-41dc-a3b0-e11fbe4fa87e","keyword":"混杂纤维","originalKeyword":"混杂纤维"},{"id":"425900df-8215-4a52-a68f-1eb0d6f5db5e","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"80816674-54ce-49ee-8226-908f41140028","keyword":"水声材料","originalKeyword":"水声材料"},{"id":"ab481824-fd7b-44cf-9dd8-2a6af141a8d3","keyword":"等效刚度","originalKeyword":"等效刚度"}],"language":"zh","publisherId":"blgfhcl200604006","title":"承载/声隐身混杂纤维复合材料的研究","volume":"","year":"2006"},{"abstractinfo":"针对任意铺层形式和任意壁厚复合材料圆形层合管件,提出一种等效抗弯刚度的计算方法。此方法采用符合复合材料圆形管件梁真实变形的变形理论,考虑横向剪切变形,非均匀扭转效应,主、次挠曲效应和层合材料的三维弹性效应,按照壳壁中实际应力状态,建立了复合材料圆形管件等效抗弯刚度的计算模型。通过与4种铺层管件的三点弯曲实验结果以及经典层合板理论计算的等效抗弯刚度进行对比,验证了计算模型的正确性。通过退化与各向同性材料抗弯刚度的计算方法进行对比,分析了计算模型的适用性。","authors":[{"authorName":"张恒铭","id":"3e063c1f-7d35-4290-a1b7-244be4c9661a","originalAuthorName":"张恒铭"},{"authorName":"李峰","id":"d3985948-73e2-4db2-b8da-e8ae7fb55b54","originalAuthorName":"李峰"},{"authorName":"潘大荣","id":"a7f72e37-9b0c-4dd6-87ce-84438d323178","originalAuthorName":"潘大荣"}],"doi":"10.13801/j.cnki.fhclxb.20151029.001","fpage":"1694","id":"c4f99be7-e95b-4777-ba27-c2d6f265e2ee","issue":"8","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":"0c5b440c-a2d9-4a0b-b73c-0a6ac3ac4465","keyword":"等效抗弯刚度","originalKeyword":"等效抗弯刚度"},{"id":"7cf0914b-ce4a-46b0-a512-b04051668048","keyword":"复合材料层合管","originalKeyword":"复合材料层合管"},{"id":"4a0f90a6-755e-4154-8f88-9cc718555d0a","keyword":"三维梁理论","originalKeyword":"三维梁理论"},{"id":"488c49d1-3542-4379-b4a8-3914e0c515c2","keyword":"三维弹性效应","originalKeyword":"三维弹性效应"},{"id":"d73ae94c-cd52-4328-a045-6298a04d7982","keyword":"经典层合板理论","originalKeyword":"经典层合板理论"}],"language":"zh","publisherId":"fhclxb201608013","title":"基于三维梁理论的复合材料层合管等效抗弯刚度","volume":"33","year":"2016"},{"abstractinfo":"为了对复合材料副簧的刚度进行匹配设计,设计了包含有复合材料副簧的主副簧总成结构。采用集中载荷法计算复合材料副簧的等效载荷,根据原钢板弹簧的挠度变化来估算复合材料副簧的等效刚度。根据钢板弹簧设计理论,对复合材料副簧的等效刚度进行匹配设计。采用 ABAQUS软件对设计的主副簧总成的总刚度进行有限元模拟,通过调整复合材料副簧的铺层数量来修正复合材料副簧的等效刚度。提出的匹配设计方法对复合材料板簧的推广应用具有重要意义。","authors":[{"authorName":"柯俊","id":"7c73f5c1-86aa-41e8-85d9-51445efdfda1","originalAuthorName":"柯俊"},{"authorName":"史文库","id":"b446c091-e8b0-47df-8b01-4f061446dbf7","originalAuthorName":"史文库"},{"authorName":"陈志勇","id":"0cd41bae-f95a-4230-875e-b0f89df020fc","originalAuthorName":"陈志勇"},{"authorName":"高博","id":"83d8a319-8891-4dc8-9640-b4ff09aacda7","originalAuthorName":"高博"},{"authorName":"袁可","id":"4e8e6166-5532-4e6c-8704-f0a7a25a73cc","originalAuthorName":"袁可"},{"authorName":"周刚","id":"b27a5e38-ef9e-42b2-aaab-b39bce972a40","originalAuthorName":"周刚"}],"doi":"10.13801/j.cnki.fhclxb.20151225.003","fpage":"1119","id":"2b8a6e68-3bd3-428f-a70c-51b9a791a13e","issue":"5","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":"703c28ac-1ce4-4855-9cac-946d1cc50c40","keyword":"客车","originalKeyword":"客车"},{"id":"1f55fcaf-c365-4878-a565-041bc2510cd6","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"cdc6a675-ca56-4465-b708-ce81c8fb66a4","keyword":"板簧","originalKeyword":"板簧"},{"id":"410c44f1-46fe-4522-aae2-1a0360a47b6b","keyword":"轻量化","originalKeyword":"轻量化"},{"id":"d82fac6d-20c9-4dcc-877a-ab2d93b71e41","keyword":"有限元","originalKeyword":"有限元"}],"language":"zh","publisherId":"fhclxb201605022","title":"复合材料副簧刚度的匹配设计方法","volume":"33","year":"2016"},{"abstractinfo":"为了解决全复合材料桁架扭转刚度缺少实验外有效表征手段的问题,首先,基于均匀化思想,依据单胞剪切刚度相等原则,将全复合材料桁架等效为闭口薄壁梁,推导其等效扭转刚度;然后提出位移转换法并测量桁架转角,对全复合材料桁架扭转刚度进行了实验研究;最后,在梁单元桁架模型中嵌入精细化接头模型,对全复合材料桁架扭转刚度进行了仿真分析.结果表明:等效及仿真结果与实验值基本吻合,等效分析方法能够有效预测全复合材料桁架的扭转刚度,桁架仿真模型具有一定的工程实用性;实验方案可靠,所提出的位移转换法能够解决小转角测量相对误差较大的问题.","authors":[{"authorName":"熊波","id":"f07e3494-2fe3-4af6-9788-4099887a56c4","originalAuthorName":"熊波"},{"authorName":"罗锡林","id":"d3449d47-92ea-4c74-927f-e37db736f778","originalAuthorName":"罗锡林"},{"authorName":"谭惠丰","id":"31ced2d1-6ceb-4781-b5f8-54a49715a015","originalAuthorName":"谭惠丰"}],"doi":"10.13801/j.cnki.fhclxb.20140627.003","fpage":"501","id":"9cda815b-1ed2-493b-8d13-41655a21e88a","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":"e2a347a7-eaf0-49c8-9887-aa82189c05c9","keyword":"复合材料桁架","originalKeyword":"复合材料桁架"},{"id":"f95a18b1-3942-44e8-b49d-69a77b687453","keyword":"扭转刚度","originalKeyword":"扭转刚度"},{"id":"ad05f4fd-92f1-4e80-b48e-4cd34f1fd9cd","keyword":"均匀化等效","originalKeyword":"均匀化等效"},{"id":"05e21f9c-af68-4b84-89fc-27cf24a0a88a","keyword":"扭转实验","originalKeyword":"扭转实验"},{"id":"da74bbfa-e760-40df-bf47-342dfe9a163f","keyword":"有限元","originalKeyword":"有限元"}],"language":"zh","publisherId":"fhclxb201502026","title":"全复合材料桁架扭转刚度分析","volume":"32","year":"2015"},{"abstractinfo":"高精度蜂窝夹层结构反射面板由经过开缝应力释放工艺处理的表层铝板和铝蜂窝芯胶接而成,为了研究缝隙所引起的夹层结构刚度损失,基于对实验数据的统计分析,考虑缝隙面积和分布等对刚度的影响,定义了缝隙对刚度的影响系数与刚度的损失系数并建立了二者之间的关系,提出了基于缝隙特征的蜂窝夹层结构刚度损失的评估方法。实验分析结果表明,缝隙对夹层结构刚度造成的损失达到一定程度后明显减缓,刚度最大损失可限定在40%。针对表板带有缝隙的夹层结构的数值分析,依据夹层结构刚度等效原则,利用刚度损失与缝隙影响系数之间的关系,可将带有缝隙的表板等效为厚度减薄的连续表板,对于模拟带有缝隙的夹层结构具有一定的应用价值。","authors":[{"authorName":"江超","id":"a427eb24-a6fa-4392-b784-c473d0968215","originalAuthorName":"江超"},{"authorName":"李东升","id":"3a90270a-fbcb-4875-ae54-87e23b3b6f5a","originalAuthorName":"李东升"},{"authorName":"任士明","id":"3da0914f-48fa-4b6a-b2e1-079f66bf6417","originalAuthorName":"任士明"},{"authorName":"周国锋","id":"1f803c03-1c64-4654-8e6f-add96aa0b5e6","originalAuthorName":"周国锋"}],"doi":"","fpage":"186","id":"0d8ee4d4-caaf-4a16-aa5b-356a026b61a2","issue":"4","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":"0284f9b2-181c-4525-9113-ccd7f0a1523a","keyword":"夹层结构","originalKeyword":"夹层结构"},{"id":"9fe75a09-d751-43b4-aa2e-c2dedcc01cf1","keyword":"缝隙特征","originalKeyword":"缝隙特征"},{"id":"5a175415-c9dc-4905-bae2-49849b0d2ef4","keyword":"刚度损失","originalKeyword":"刚度损失"},{"id":"c4afdeca-ec6d-442c-af44-42bd8341abe2","keyword":"数值模拟","originalKeyword":"数值模拟"},{"id":"51bbc50f-01f5-42f1-a2cf-c9dec2f46db3","keyword":"反射面板","originalKeyword":"反射面板"}],"language":"zh","publisherId":"fhclxb201204030","title":"基于缝隙特征的蜂窝夹层结构刚度损失评估及应用","volume":"29","year":"2012"},{"abstractinfo":"研究植入工艺参数和材料性能对X-cor夹层结构剪切刚度的影响.通过对pin端部所受约束的细节分析,得到端部约束的三个等效弹簧系数表达式,用于X-cor夹层结构剪切刚度模型计算,并考察pin植入角度、端部斜切角、植入端深度、直径、材料性能和泡沫材料性能等参数对剪切刚度的影响规律.计算结果与试验结果吻合较好,该方法可用于预测X-cor夹层结构剪切刚度.参数分析结果表明,通过增大pin植入角度、pin轴向刚度以及pin直径可显著提高X-cor夹层结构的剪切刚度;pin端部斜切角和植入端深度是次要影响因素;另外,当选用的泡沫材料较刚硬时,不能忽略泡沫材料对结构剪切刚度的贡献.","authors":[{"authorName":"陈海欢","id":"0c937e24-bbe1-4745-a173-7b511b97be03","originalAuthorName":"陈海欢"},{"authorName":"张晓晶","id":"9175f41a-10ad-4217-a533-169b1886f0e9","originalAuthorName":"张晓晶"},{"authorName":"汪海","id":"eec4448c-0d10-49cf-a957-cf84d23490c8","originalAuthorName":"汪海"}],"doi":"10.3969/j.issn.1005-5053.2010.4.016","fpage":"81","id":"0ef3a535-264e-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"},"keywords":[{"id":"82cd5c77-2993-4edc-82e5-b0f6d0b08ada","keyword":"蜂窝夹层板","originalKeyword":"蜂窝夹层板"},{"id":"218aeae8-3ec6-4731-8824-00a91ec00d6d","keyword":"三明治夹芯板","originalKeyword":"三明治夹芯板"},{"id":"9ce96d92-c9f6-49b6-96ec-f5184e176cf4","keyword":"固有频率","originalKeyword":"固有频率"},{"id":"6ea73b2b-9f23-46c2-b1c9-4e2c761f7a45","keyword":"等效方法","originalKeyword":"等效方法"}],"language":"zh","publisherId":"yhclgy201502003","title":"基于等效理论的蜂窝夹层板强度等效分析","volume":"45","year":"2015"},{"abstractinfo":"用SHS技术制备的纳米共晶晶须复相陶瓷具有较大的断裂韧性和较高的塑性形变行为,其组织结构以纳米共晶晶须为基体.运用Mori-Tanaka方法研究了复合共晶晶须的等效本征应变,并得到了复合共晶晶须的应力应变关系.通过应力应变关系计算出复合共晶晶须的刚度,复合共晶晶须为横观各向同性,具有5个独立的弹性常数.根据复相陶瓷的应变均值,考虑复合共晶晶须方位的随机性,计算出材料的有效弹性模量和泊松比,复相陶瓷材料为各向同性体.","authors":[{"authorName":"倪新华","id":"d4a27666-cb33-4203-a99c-622672d7e992","originalAuthorName":"倪新华"},{"authorName":"刘协权","id":"476140cb-ec03-4973-b03d-929d9beaca1c","originalAuthorName":"刘协权"},{"authorName":"赵忠民","id":"dc1ef99f-25ee-445c-a62b-58d0da1f23cb","originalAuthorName":"赵忠民"}],"doi":"","fpage":"597","id":"1b35fe4b-79e2-4e21-b2f4-cdb07beac094","issue":"z1","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":"5424a8dd-674e-477b-b97b-a60008656435","keyword":"纳米共晶晶须","originalKeyword":"纳米共晶晶须"},{"id":"dfb9476f-ff4d-4acb-b73d-52a0a2e7e528","keyword":"刚度预报","originalKeyword":"刚度预报"},{"id":"18ade8d8-d3b4-46a3-83d5-46cf73f1c4a8","keyword":"Mori-Tanaka方法","originalKeyword":"Mori-Tanaka方法"},{"id":"f92d2f4e-2db7-493e-a8cb-576041d5dd54","keyword":"横观各向同性","originalKeyword":"横观各向同性"},{"id":"da5424d2-bc12-4364-9c2a-7f2153cf438a","keyword":"各向同性","originalKeyword":"各向同性"}],"language":"zh","publisherId":"xyjsclygc2005z1161","title":"纳米共晶晶须复相陶瓷的刚度预报","volume":"34","year":"2005"}],"totalpage":209,"totalrecord":2082}