{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":4,"startPagecode":1},"records":[{"abstractinfo":"植物纤维与聚合物形成的复合体系易堵塞毛细管流变仪,不适宜用毛细管流变仪测量流变性能.文中提出了一种利用转矩流变仪测量植物纤维/聚合物复合材料流变性能的表征方法,由转矩流变仪测得的平衡扭矩和平衡温度数据拟含得到低密度聚乙烯(LDPE)/棉秆皮纤维复合材料的幂率模型参数,并研究了复合体系中棉秆皮纤维含量对复合材料流变性能的影响.结果表明,加入棉秆皮纤维后复合材料剪切变稀现象随纤维含量的增加而更为明显.","authors":[{"authorName":"李展<span style=\"color:red\">洪</span>","id":"b83bce64-f54c-4d5c-9a98-682e7537c1b3","originalAuthorName":"李展洪"},{"authorName":"<span style=\"color:red\">冯</span><span style=\"color:red\">彦</span><span style=\"color:red\">洪</span>","id":"dca1f9bf-8954-4ea2-8dac-27734b5ae519","originalAuthorName":"冯彦洪"},{"authorName":"刘斌","id":"bcc61f14-64bd-46d0-a7d8-6875091922de","originalAuthorName":"刘斌"},{"authorName":"徐百平","id":"3a9cb127-8174-4770-97fb-d18b853da718","originalAuthorName":"徐百平"},{"authorName":"瞿金平","id":"b7e54507-e8f3-49a9-a68a-ec4af27256ea","originalAuthorName":"瞿金平"},{"authorName":"何和智","id":"0bc4dc1e-4716-4ab2-a878-8ad6390a841a","originalAuthorName":"何和智"}],"doi":"","fpage":"171","id":"4acd3e75-b370-4731-99ff-c7e6be443a00","issue":"9","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"6c8d5dca-f33a-4d38-a968-a6c7b313039c","keyword":"低密度聚乙烯/棉秆皮纤维复合材料","originalKeyword":"低密度聚乙烯/棉秆皮纤维复合材料"},{"id":"27982995-6a45-4da0-a74a-092ec2ad2753","keyword":"转矩流变仪","originalKeyword":"转矩流变仪"},{"id":"aa17956a-fe68-4d9a-bf46-0e57c2114dc9","keyword":"幂率模型","originalKeyword":"幂率模型"},{"id":"f6ac6dd7-a86f-4a6b-8ad4-b578e520a18e","keyword":"取向","originalKeyword":"取向"}],"language":"zh","publisherId":"gfzclkxygc201009045","title":"植物纤维/聚合物复合材料流变参数的转矩流变表征方法","volume":"26","year":"2010"},{"abstractinfo":"对几种中药渣（山芝麻,葫芦茶,三叉苦,广霍香）进行蒸汽爆破处理,以马来酸酐改性无规共聚聚丙烯（MAPP）作为相容剂,与聚丙烯（PP）复合制备复合材料,实现几种中药渣废弃物资源的高值化利用。分析了各药渣的主要成分,用扫描电镜（SEM）观察药渣及复合材料拉伸断面的形貌。结果表明,蒸汽爆破处理药渣可使纤维束解离出纤维细胞作为增强材料;药渣纤维的种类影响复合材料的拉伸和弯曲性能,选用木质化程度高、半纤维素含量低、杂细胞少的药渣有利于制备出综合性能较好的复合材料。","authors":[{"authorName":"<span style=\"color:red\">冯</span><span style=\"color:red\">彦</span><span style=\"color:red\">洪</span>","id":"6efacec1-bee7-4bbf-a9ea-2ecf5e2b375e","originalAuthorName":"冯彦洪"},{"authorName":"张叶青","id":"0c85127f-ab83-4f11-9cbc-c0fbb9eb2c09","originalAuthorName":"张叶青"},{"authorName":"李向丽","id":"414224d9-61af-4490-b795-2535ca3667ec","originalAuthorName":"李向丽"},{"authorName":"瞿金平","id":"408f63bf-9625-4796-abfc-d8deef230a4c","originalAuthorName":"瞿金平"},{"authorName":"何平伟","id":"b41eeade-696b-4c4e-b5b7-c612dac06e62","originalAuthorName":"何平伟"}],"doi":"","fpage":"121","id":"c7db7434-076e-4bc7-a7eb-b13a492e4b4c","issue":"5","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"323ed9e6-d6a1-4bc6-9482-3d0fcc57e4bc","keyword":"中药渣","originalKeyword":"中药渣"},{"id":"a7577165-98f2-4b7f-9d0f-7224ce1864d2","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"b9742b81-c9ac-49e9-b57f-5be98969611b","keyword":"蒸汽爆破","originalKeyword":"蒸汽爆破"}],"language":"zh","publisherId":"gfzclkxygc201205032","title":"几种中药渣/PP复合材料的制备与性能","volume":"28","year":"2012"},{"abstractinfo":"从加工工艺和设备改进入手改善Mg(OH)2在高密度聚乙烯(HDPE)中的分散性.将电磁振动技术和三螺杆挤出机结合起来,用三螺杆动态混炼挤出机挤出HDPE/Mg(OH)2,通过对挤出物料中Mg(OH)2的分散性研究,得出三螺杆动态混炼对Mg(OH)2的分散性和HDPE/Mg(OH)2力学性能的影响规律,并对在不同振动参数(振幅、频率)下制取标准力学性能测试试样与稳态挤出时试样力学性能的比较获取最优的振动参数范围,解决了因Mg(OH)2填充量过高而严重影响复合材料力学性能的问题.","authors":[{"authorName":"胡松喜","id":"9b187852-4080-4555-96e9-a116a8503f43","originalAuthorName":"胡松喜"},{"authorName":"瞿金平","id":"255f9577-3d18-42a9-979c-a95ef4f6fe5c","originalAuthorName":"瞿金平"},{"authorName":"王松若","id":"9eac0471-2d69-453a-8438-c82550cab187","originalAuthorName":"王松若"},{"authorName":"<span style=\"color:red\">冯</span><span style=\"color:red\">彦</span><span style=\"color:red\">洪</span>","id":"81693cc8-366f-4212-b812-93d7c157d26d","originalAuthorName":"冯彦洪"},{"authorName":"曾显宝","id":"fba29c02-2407-4646-9e45-954848161798","originalAuthorName":"曾显宝"}],"doi":"","fpage":"115","id":"e874e156-eb84-4a54-a123-703ff4d800f7","issue":"5","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"c7530740-4255-4737-8953-f5fb24e37423","keyword":"三螺杆","originalKeyword":"三螺杆"},{"id":"c9a1c4f0-00a3-411e-964f-56c71c1860cb","keyword":"振动力场","originalKeyword":"振动力场"},{"id":"8c167039-bbae-451d-bfa6-edc10d97d44d","keyword":"动态混炼","originalKeyword":"动态混炼"},{"id":"9800fe6e-0d54-465b-a0b1-b9b2722c71ab","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"gfzclkxygc200905033","title":"三螺杆动态混炼挤出HDPE/Mg(OH)2填充体系的力学性能","volume":"25","year":"2009"},{"abstractinfo":"根据对称性与周期性,建立了混沌螺杆螺槽的混合过程动力学模型.采用有限体积方法,得到一个周期长度速度场数值解,将结果映射到3个周期长度的相空间内对混沌混合过程动力学进行分析与表征.结果表明,常规的层流混合和混沌混合区域共存,两种混合区域通过\"8\"字型同宿轨道包围的KAM岛分割开来,内部为常规混合区域,外围为混沌混合区域.示踪粒子在三维重构的相空间内动力学行为清楚地刻画了系统向混沌进发的过程及速度.另外,由于长度有限,混沌混合的作用受到限制,不再具有无穷的自相似结构,可以采用KAM岛的区域大小来表征混合.","authors":[{"authorName":"徐百平","id":"12f7c5c0-9d58-43e1-8d2e-bfe43d698b2d","originalAuthorName":"徐百平"},{"authorName":"宋建","id":"57dc07f0-83f2-4b01-8785-7e816118aaaf","originalAuthorName":"宋建"},{"authorName":"彭响方","id":"5a4d8be1-c585-4d52-91de-78bfb829a507","originalAuthorName":"彭响方"},{"authorName":"谢芳","id":"206d073f-5a63-4550-b9db-dc4e61fbac22","originalAuthorName":"谢芳"},{"authorName":"<span style=\"color:red\">冯</span><span style=\"color:red\">彦</span><span style=\"color:red\">洪</span>","id":"3125a7b5-bb21-4f01-b90f-927eca1cb4a1","originalAuthorName":"冯彦洪"}],"doi":"","fpage":"34","id":"faf8cbad-0244-486c-b79f-503ed0600fb2","issue":"12","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"d507dade-a496-4903-98b9-8d613bf0b50d","keyword":"混沌挤出","originalKeyword":"混沌挤出"},{"id":"de22b467-65fb-4789-9c2a-d080a55597e3","keyword":"混合","originalKeyword":"混合"},{"id":"de2b8e38-0403-402d-8c8a-3ad8b2750583","keyword":"动力学行为","originalKeyword":"动力学行为"},{"id":"f61c4806-32ef-4d32-941e-595611d7076c","keyword":"相空间","originalKeyword":"相空间"},{"id":"2befdcd2-2077-41c8-aeeb-5aa42946dbbb","keyword":"分析与表征","originalKeyword":"分析与表征"}],"language":"zh","publisherId":"gfzclkxygc200812008","title":"混沌挤出过程相空间动力学行为分析与表征","volume":"24","year":"2008"},{"abstractinfo":"将振动场引入聚合物塑化挤出的全过程,建立了振动挤出机的聚合物动态解析熔融模型.振动场的引入使挤出机的熔融塑化能力得到了很大的提高,熔融段的长度随着振动频率和振幅的增大而减少.在该模型中,随着熔融过程的进行,熔体的厚度缓慢增加,而固体床缓慢减少,直到聚合物熔体填满整个螺槽横截面;在稳定情况下,熔融段的长度不变,聚合物颗粒进入料筒的速度与挤出机的熔融速度以及产量相等.但是,当熔融段的长度达到某一稳定值后,再增大振幅或频率,熔融段的长度不再发生明显的变化.用该模型能很好地预测振动挤出机的成型参数,得到优化条件.将计算值与实验值比较验证了各振动参数(振幅和频率)对振动挤出机塑化熔融能力的影响.","authors":[{"authorName":"曾广胜","id":"c73d097a-a367-4086-b5e0-dd3a4e8991e1","originalAuthorName":"曾广胜"},{"authorName":"瞿金平","id":"8f2c4a22-e4b6-404f-aed4-904dcaa452af","originalAuthorName":"瞿金平"},{"authorName":"<span style=\"color:red\">冯</span><span style=\"color:red\">彦</span><span style=\"color:red\">洪</span>","id":"c589c8ab-59b8-425d-b550-75de3782708d","originalAuthorName":"冯彦洪"}],"doi":"10.3321/j.issn:1005-3093.2006.01.013","fpage":"59","id":"a9a3e8e1-b841-490e-b3da-2ad485bd7c66","issue":"1","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":"b89f5350-3d4b-4ccd-a68c-8ad7b56b5da0","keyword":"材料科学基础学科","originalKeyword":"材料科学基础学科"},{"id":"4390c329-f89b-4c0e-8a23-f1fbaa386d02","keyword":"熔融模型","originalKeyword":"熔融模型"},{"id":"a88345f3-ef2f-420a-afd8-c9af120466ea","keyword":"挤出机","originalKeyword":"挤出机"},{"id":"2f1d4360-d858-4387-b040-4f3004ad2f0f","keyword":"聚合物","originalKeyword":"聚合物"},{"id":"650e3048-54d8-480e-a5e2-6e86cd9e7f5e","keyword":"振动","originalKeyword":"振动"}],"language":"zh","publisherId":"clyjxb200601013","title":"振动场作用下聚合物的新型动态塑化熔融模型","volume":"20","year":"2006"},{"abstractinfo":"对PMI泡沫夹层结构整流罩<span style=\"color:red\">冯</span>卡门锥段成型技术进行了研究,通过对玻璃钢面板及其泡沫夹层结构性能、面板成型、泡沫热成形、泡沫拼接、玻璃钢泡沫夹层结构成型及无损检测等技术研究,确定了玻璃钢外面板、预先固化,然后与泡沫等复合组装,最后铺覆内面板,整体进罐固化的成型工艺.结果表明,玻璃钢面板纵、横向拉伸强度为602、593MPa,模量为26.0、27.2 GPa,满足设计强度≥350MPa、模量≥25GPa的要求；玻璃钢/PMI泡沫夹层结构泡沫密度为(110±10)kg/m3,厚度28mm,纵、横向侧压强度为32.9、30.5MPa、模量为2.31、2.38GPa,满足设计指标侧压强度≥25MPa、模量≥2.0GPa的要求,采用玻璃钢/PMI 泡沫夹层结构分步固化成型工艺研制的首件新型号整流罩<span style=\"color:red\">冯</span>卡门锥段,满足设计使用要求.","authors":[{"authorName":"赵锐霞","id":"6d0b970d-2e9d-4c82-a1fa-3158a003ccda","originalAuthorName":"赵锐霞"},{"authorName":"尹亮","id":"922fc883-6865-4df3-8393-3eb39221466c","originalAuthorName":"尹亮"},{"authorName":"潘玲英","id":"c65837a1-503f-4cfd-8773-4d5d7a5ed0c9","originalAuthorName":"潘玲英"}],"doi":"10.3969/j.issn.1007-2330.2012.04.014","fpage":"58","id":"a73bd1ed-8b1a-4faf-aaa8-43f7882b4829","issue":"4","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":"b4460ffb-fdfa-41e7-bfa6-371091ce4719","keyword":"泡沫夹层结构","originalKeyword":"泡沫夹层结构"},{"id":"6144557c-b4d4-441d-b35e-df3eea9ac029","keyword":"<span style=\"color:red\">冯</span>卡门锥段","originalKeyword":"冯卡门锥段"},{"id":"12578f5e-24e0-4ce5-9465-6b28d57cf2dd","keyword":"成型技术","originalKeyword":"成型技术"}],"language":"zh","publisherId":"yhclgy201204014","title":"PMI 泡沫夹层结构整流罩<span style=\"color:red\">冯</span>卡门锥段成型技术研究","volume":"42","year":"2012"},{"abstractinfo":"对江西<span style=\"color:red\">洪</span>州窑从东汉晚期至晚唐五代8期400个瓷胎样品进行了中子活化分析, 分析结果显示碱金属元素Na和Rb、碱土金属元素Ba及Fe等作为胎的助熔剂元素随年代的变化趋势相似, 都呈现出两头高中间低的U字形变化规律, 其中Fe作为呈色元素, 其含量的高低与瓷胎颜色的深浅是一致的.分析结果还揭示<span style=\"color:red\">洪</span>州窑的发展与衰落以及窑址的不断变迁可能都与制瓷原料的发现与消耗有关.对分析数据进行主成分分析, 可以将不同时期烧制的瓷胎样品大致分为5组: (1)东汉晚期东吴时期; (2)两晋和南朝时期; (3)隋代; (4)初唐和盛唐时期; (5)晚唐五代时期.","authors":[{"authorName":"<span style=\"color:red\">冯</span>向前","id":"bb73e52d-559b-4aa0-9509-23f003727157","originalAuthorName":"冯向前"},{"authorName":"<span style=\"color:red\">冯</span>松林","id":"13c25759-1db8-425f-b21e-84ae056cff1f","originalAuthorName":"冯松林"},{"authorName":"张文江","id":"8d96cc12-6a67-4944-817b-215bb3dec0c3","originalAuthorName":"张文江"},{"authorName":"樊昌生","id":"e5d11a72-233a-41c4-a38d-1904e5cfad2a","originalAuthorName":"樊昌生"},{"authorName":"权奎山","id":"1f96e504-74c9-4ce8-88b5-559409c26f07","originalAuthorName":"权奎山"}],"doi":"10.3969/j.issn.1007-4627.2005.01.043","fpage":"142","id":"70359f2b-8369-4007-987f-7444de816237","issue":"1","journal":{"abbrevTitle":"YZHWLPL","coverImgSrc":"journal/img/cover/YZHWLPL.jpg","id":"78","issnPpub":"1007-4627","publisherId":"YZHWLPL","title":"原子核物理评论   "},"keywords":[{"id":"5d15414d-1511-4f0b-9870-b7212e945429","keyword":"核分析技术","originalKeyword":"核分析技术"},{"id":"b1f77f43-f953-4410-ad65-387980a986c6","keyword":"<span style=\"color:red\">洪</span>州窑古瓷","originalKeyword":"洪州窑古瓷"},{"id":"3118b21f-e76c-44d6-895c-ff785bb4462d","keyword":"元素特征","originalKeyword":"元素特征"}],"language":"zh","publisherId":"yzhwlpl200501043","title":"历代<span style=\"color:red\">洪</span>州窑古瓷的元素组成特征的中子活化分析研究","volume":"22","year":"2005"},{"abstractinfo":"","authors":[{"authorName":"吴钰重","id":"9c027aa4-b103-451d-8e97-5f473eac2352","originalAuthorName":"吴钰重"}],"doi":"10.3969/j.issn.1000-6826.2015.05.01","fpage":"1","id":"0506a7f0-4c97-4d66-a669-f34c1c16bd2f","issue":"5","journal":{"abbrevTitle":"JSSJ","coverImgSrc":"journal/img/cover/3abe017a-2574-4821-8152-4ae974ef0471.jpg","id":"47","issnPpub":"1000-6826","publisherId":"JSSJ","title":"金属世界"},"keywords":[{"id":"d9b0bd3a-6769-4f19-8833-73a919a0d3ad","keyword":"","originalKeyword":""}],"language":"zh","publisherId":"jssj201505001","title":"<span style=\"color:red\">冯</span>春：勤恳为师路，执着科研心","volume":"","year":"2015"},{"abstractinfo":"","authors":[{"authorName":"夏杰生","id":"336f3e93-6c5b-4a63-a2d6-7bac073d5de6","originalAuthorName":"夏杰生"}],"doi":"10.3969/j.issn.1000-6826.2004.03.007","fpage":"17","id":"1b7cf592-b2d6-4342-a5eb-42d1a0b5de40","issue":"3","journal":{"abbrevTitle":"JSSJ","coverImgSrc":"journal/img/cover/3abe017a-2574-4821-8152-4ae974ef0471.jpg","id":"47","issnPpub":"1000-6826","publisherId":"JSSJ","title":"金属世界"},"keywords":[{"id":"1bce85db-6028-4171-badb-55521507c09e","keyword":"","originalKeyword":""}],"language":"zh","publisherId":"jssj200403007","title":"迎接第五次提速--铁路用钢专家董志<span style=\"color:red\">洪</span>教授谈高速铁路与钢轨生产","volume":"","year":"2004"},{"abstractinfo":"以1,4-双(4-氨基-2-三氟甲基苯氧基)苯(6FAPB)为含氟二胺单体,均苯四甲酸二酐(PMDA)和1,2,3,4-环丁烷四酸二酐(CBDA)为二酐单体,经低温溶液缩聚反应得到聚酰胺酸,再经热酰亚胺化处理制备出含氟共聚聚酰亚胺(CPI)薄膜.采用红外(IR)、紫外(UV-Vis)、溶解性测试等对CPI进行结构与性能表征,考察两种二酐单体的不同物质的量之比对共聚聚酰亚胺光学性能和溶解性的影响.结果表明:随着脂环二酐CBDA摩尔配比的增加,CPI薄膜在410 nm处的光透过率逐渐增加,薄膜颜色逐渐变浅,溶解性有所改善.","authors":[{"authorName":"鲁云华","id":"09c92763-7a3d-4860-aac7-8c0672f668bd","originalAuthorName":"鲁云华"},{"authorName":"赵<span style=\"color:red\">洪</span>斌","id":"e79d0f1c-bcd6-4a61-b298-1e6a823e69ff","originalAuthorName":"赵洪斌"},{"authorName":"迟海军","id":"4d06d6df-470b-4836-9e14-6a9e68a798fb","originalAuthorName":"迟海军"},{"authorName":"董岩","id":"65896635-a332-4856-ad38-77ddf2d37753","originalAuthorName":"董岩"},{"authorName":"肖国勇","id":"6738b002-e0b1-4cb3-831f-bed85cb05445","originalAuthorName":"肖国勇"},{"authorName":"胡知之","id":"7c4d40f4-1977-435e-ab13-ebd318d5c61d","originalAuthorName":"胡知之"}],"doi":"","fpage":"1","id":"e73a30ed-13db-43ea-bea4-6581231b1334","issue":"1","journal":{"abbrevTitle":"JYCL","coverImgSrc":"journal/img/cover/JYCL.jpg","id":"50","issnPpub":"1009-9239","publisherId":"JYCL","title":"绝缘材料"},"keywords":[{"id":"6a5dd4f9-b106-4267-949f-792555f6ac67","keyword":"聚酰亚胺","originalKeyword":"聚酰亚胺"},{"id":"81daa9c0-a188-4bf7-becd-eb9025259934","keyword":"共缩聚","originalKeyword":"共缩聚"},{"id":"4fa37438-567f-4a66-bd23-7b745ed05d4e","keyword":"含氟","originalKeyword":"含氟"},{"id":"e0608fa6-5b7a-44b4-9f6c-533a67987ef0","keyword":"结构与性能","originalKeyword":"结构与性能"}],"language":"zh","publisherId":"jycltx201301001","title":"含氟共聚聚酰亚胺的合成与性能研究鲁云华,赵<span style=\"color:red\">洪</span>斌,迟海军,董岩,肖国勇,胡知之","volume":"","year":"2013"}],"totalpage":4,"totalrecord":31}