{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"综述了国内外瓦楞纸板、蜂窝纸板和<span style=\"color:red\">纸浆模塑制品</span>等纸质结构型缓冲包装材料结构缓冲的研究现状,并分别总结了上述材料国内外的研究侧重点:国内的研究多处于对现有材料的试验阶段;而国外则侧重于用力学理论基础知识来解释这些材料的力学性能,并用有限元软件对其力学模型进行仿真,该研究结果对于不同材质的结构型材料具有一定的普适性.在此基础上得出开发新型结构型材料,寻求普适性的缓冲性能表征方法是下一步研究的方向.","authors":[{"authorName":"王冬梅","id":"c073d50f-3c59-42e8-95aa-4ccdb992d02e","originalAuthorName":"王冬梅"},{"authorName":"王志伟","id":"6835c917-3df9-4b79-a92b-058f6ed2ba85","originalAuthorName":"王志伟"}],"doi":"","fpage":"43","id":"1faa213d-d6be-47ab-a7ab-4a43f14a755b","issue":"6","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"aa5ddfa8-d451-4600-b24d-57e35e8aeb5c","keyword":"缓冲材料","originalKeyword":"缓冲材料"},{"id":"4230f15c-9737-4d7e-8b03-91ba9745e0ad","keyword":"结构","originalKeyword":"结构"},{"id":"ccdbefcf-36f3-4859-9b7a-4d16e5b4d262","keyword":"瓦楞纸板","originalKeyword":"瓦楞纸板"},{"id":"3e0e131c-8a6a-4062-a619-0f79e6b45125","keyword":"蜂窝纸板","originalKeyword":"蜂窝纸板"},{"id":"e6700375-f4ba-4233-b22d-572dcf89928e","keyword":"<span style=\"color:red\">纸浆模塑制品</span>","originalKeyword":"纸浆模塑制品"}],"language":"zh","publisherId":"cldb200706011","title":"纸质结构型包装材料缓冲性能研究进展","volume":"21","year":"2007"},{"abstractinfo":"<span style=\"color:red\">模塑</span>成型是高分子材料成型的重要手段,而<span style=\"color:red\">制品</span>的成型收缩则是决定高分子<span style=\"color:red\">模塑制品</span>精度及合格率的关键因素.文中以可视化模具系统为核心,通过对<span style=\"color:red\">制品</span>内部添加活性炭颗粒等特征点,提出了一种高分子材料<span style=\"color:red\">模塑</span>成型<span style=\"color:red\">制品</span>内部收缩的可视化测定及分析方法,并将该方法用于聚氨酯<span style=\"color:red\">制品</span>内部收缩率的测量与分析.结果显示,该方法能直观形象地呈现<span style=\"color:red\">制品</span>内部收缩:<span style=\"color:red\">制品</span>的内部收缩在浇口附近有明显的负收缩;<span style=\"color:red\">制品</span>长度收缩随流动路径的增加而增大,宽度收缩由中心线向两侧减小.","authors":[{"authorName":"姜开宇","id":"22716b01-5524-4ebc-91ef-281f8747fcec","originalAuthorName":"姜开宇"},{"authorName":"孙合庆","id":"b3881a27-c55a-4a44-9cf6-982dcd62f4bf","originalAuthorName":"孙合庆"},{"authorName":"段飞","id":"2b064975-7f9e-4929-b0c0-49c0b855118f","originalAuthorName":"段飞"}],"doi":"","fpage":"84","id":"0d19ef18-08c2-43fe-8bf9-6221ce13d3d1","issue":"11","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":"44e02ebb-87e1-4483-8e82-e533f6680013","keyword":"<span style=\"color:red\">模塑</span>成型","originalKeyword":"模塑成型"},{"id":"4267609e-9962-4557-8b75-45f6cd226846","keyword":"内部收缩率","originalKeyword":"内部收缩率"},{"id":"57dcf0c9-22ed-44ca-9161-893f336c6713","keyword":"可视化测定","originalKeyword":"可视化测定"}],"language":"zh","publisherId":"gfzclkxygc201311020","title":"<span style=\"color:red\">模塑制品</span>内部成型收缩特性的可视化测定方法","volume":"29","year":"2013"},{"abstractinfo":"概述了聚合物注<span style=\"color:red\">塑制品</span>的取向机理,取向研究手段.介绍了应用Moldflow软件模拟以及使用偏光显微镜、傅立叶偏光红外光谱仪研究动态注<span style=\"color:red\">塑制品</span>取向结构的初步结果,指出动态下取向效应明显强于稳态,<span style=\"color:red\">制品</span>皮层取向产生的光学效应明显强于芯层,红外偏光技术能够较好地对取向态进行定量测试.","authors":[{"authorName":"吴宏武","id":"07aab81b-d42f-44e1-80a9-eed43f4d28b5","originalAuthorName":"吴宏武"},{"authorName":"高军","id":"0e92c4ee-61c0-41ff-8e33-85ffe02536cb","originalAuthorName":"高军"}],"doi":"","fpage":"59","id":"104d3b25-4e04-4394-8253-8dd24cee6dbe","issue":"8","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"2fe32627-c00a-4f69-9fa0-28a715ba8131","keyword":"注<span style=\"color:red\">塑制品</span>","originalKeyword":"注塑制品"},{"id":"096be541-e9cb-4eef-bbc8-c8cdcb76d300","keyword":"分子链","originalKeyword":"分子链"},{"id":"1905a09b-b48f-42a7-abb2-eca7e52d962e","keyword":"取向","originalKeyword":"取向"},{"id":"5987f0af-78d0-4c4a-becb-d395a832b155","keyword":"动态注塑","originalKeyword":"动态注塑"}],"language":"zh","publisherId":"cldb200708016","title":"聚合物注<span style=\"color:red\">塑制品</span>的取向研究","volume":"21","year":"2007"},{"abstractinfo":"翘曲变形是注<span style=\"color:red\">塑制品</span>的一种严重缺陷,而工艺参数直接影响<span style=\"color:red\">制品</span>的质量,因此建立翘曲与工艺参数之间的关系模型并求得最优的工艺参数对<span style=\"color:red\">制品</span>质量的改善非常关健.文中运用Fractional Factorial方法从众多的实脸因子中找出与塑件翘曲量密切相关的独立因子和交互因子,然后采用具有高度非线性识别能力的人工神经网络与遗传算法相结合的方法,建立塑件翘曲量与主要影响工艺参数之间的关系模型.将人工神经网络预测结果和计算机辅助工程软件模拟结果进行比较和误差分析,显示出该方法的可靠性.实验结果表明,该方法能明显提高塑件的质量,通过优化可使翘曲量减小74.06%.","authors":[{"authorName":"赵建","id":"af2704f5-9117-43ea-8692-f90477cdfb40","originalAuthorName":"赵建"},{"authorName":"张勤星","id":"52abc60a-a980-47c4-9993-c654485f9518","originalAuthorName":"张勤星"}],"doi":"","fpage":"167","id":"0f81551b-8afa-4fbb-b254-80ff08b042f0","issue":"10","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":"4a05678b-3af9-4f8c-8a8e-bdba7d79bbdc","keyword":"注塑成型","originalKeyword":"注塑成型"},{"id":"5ecb0da8-3ce5-4d7f-a593-912d91cf4f31","keyword":"工艺优化","originalKeyword":"工艺优化"},{"id":"758c126e-2559-478e-9d3d-bc7997417b6f","keyword":"Fractional Factorial方法","originalKeyword":"Fractional Factorial方法"},{"id":"118a43c4-37d7-4687-beab-b0ebd54d06aa","keyword":"神经网络","originalKeyword":"神经网络"},{"id":"b4529503-6ea9-45ee-b616-62c1773a7d47","keyword":"遗传算法","originalKeyword":"遗传算法"}],"language":"zh","publisherId":"gfzclkxygc201010044","title":"注<span style=\"color:red\">塑制品</span>的翘曲优化与分析","volume":"26","year":"2010"},{"abstractinfo":"通过注塑成型数值模拟和Plackett-Burman 实验设计相结合,以翘曲度评价注<span style=\"color:red\">塑制品</span>的翘曲变形情况,分析聚苯乙烯材料的流变特性参数和PVT特性参数对注<span style=\"color:red\">塑制品</span>变形的影响情况来研究材料特性对注<span style=\"color:red\">塑制品</span>尺寸的影响.结果表明,同一厂家生产不同牌号的同种材料引起的变形情况差距很大,文中研究的GPPS玻璃化转变时零压下的比容是注<span style=\"color:red\">塑制品</span>尺寸最重要的影响因素,玻璃化转变温度也有较大的影响.","authors":[{"authorName":"李吉泉","id":"733d9f20-297d-4916-a232-e68e8903c8a6","originalAuthorName":"李吉泉"},{"authorName":"姜少飞","id":"d494fefd-49e1-4e0a-869c-a7c1d7618faf","originalAuthorName":"姜少飞"},{"authorName":"李德群","id":"86048c8d-6478-48ad-b67e-266c680b9db5","originalAuthorName":"李德群"}],"doi":"","fpage":"160","id":"9fc06228-a731-428c-9068-58f2409f6967","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":"0fa219a5-a94d-40d3-a1d3-25b78af66342","keyword":"注塑成型","originalKeyword":"注塑成型"},{"id":"bc230b6a-4fdb-4bc2-bc48-b0d49083f4aa","keyword":"材料特性","originalKeyword":"材料特性"},{"id":"66758f8d-ff56-48a2-8332-cbfc898b1595","keyword":"<span style=\"color:red\">制品</span>尺寸","originalKeyword":"制品尺寸"}],"language":"zh","publisherId":"gfzclkxygc201012043","title":"GPPS材料特性对注<span style=\"color:red\">塑制品</span>尺寸的影响分析","volume":"26","year":"2010"},{"abstractinfo":"采用等规聚丙烯材料,选取弹性模量和屈服强度作为微<span style=\"color:red\">制品</span>力学性能的指标,基于正交实验设计进行微注塑成型实验以成型微拉伸试样,采用直观分析、信噪比分析及方差分析对微试样的拉伸实验结果进行分析,研究工艺参数对厚度1.0 mm,0.5mm和0.2 mrn的微注<span style=\"color:red\">塑制品</span>力学性能的影响规律及重要性,并分析尺度效应对微<span style=\"color:red\">制品</span>力学性能的影响.实验结果表明,不同尺度下,各个工艺参数对微<span style=\"color:red\">制品</span>力学性能的影响规律和重要性均不同,且随着尺寸的减小,微注<span style=\"color:red\">塑制品</span>的拉伸屈服强度增大,弹性模量增大.","authors":[{"authorName":"张建波","id":"181db7d3-a249-4b04-b50d-83de40e8b5d6","originalAuthorName":"张建波"},{"authorName":"王利霞","id":"c7bb8f25-32a8-4e6b-91d4-4625faedc832","originalAuthorName":"王利霞"},{"authorName":"王心超","id":"c9f0ac31-25e0-4178-8f41-75007ef4f97f","originalAuthorName":"王心超"},{"authorName":"刘晓东","id":"1fd206ec-3266-4363-997d-8948a65a75ee","originalAuthorName":"刘晓东"},{"authorName":"蒋林","id":"51bec5ad-477d-48ad-88d6-0fdbb77f8130","originalAuthorName":"蒋林"},{"authorName":"卞宁","id":"4a64162e-2d5d-41b0-8269-271520b865a8","originalAuthorName":"卞宁"},{"authorName":"张扬","id":"94a13fc0-7fe6-413e-acc3-6f787bbc4deb","originalAuthorName":"张扬"},{"authorName":"李倩","id":"108ab2c6-0180-465d-b425-cac53100c15a","originalAuthorName":"李倩"}],"doi":"","fpage":"124","id":"0144797c-e402-4079-8458-45bc5ebc77f4","issue":"2","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":"0ab55867-8c7f-487a-aec3-c38f0db23d9a","keyword":"微注<span style=\"color:red\">塑制品</span>","originalKeyword":"微注塑制品"},{"id":"db156a29-58a3-4e04-b2dc-ea5da661f257","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"7a4c9019-56e8-4ce5-a0a2-bfc1bbcc0323","keyword":"工艺参数","originalKeyword":"工艺参数"},{"id":"e4a13147-60ec-40db-a230-152b0d1d0f36","keyword":"正交实验","originalKeyword":"正交实验"},{"id":"90a46d1d-88dd-4adf-a35d-39fd24fa059d","keyword":"尺度效应","originalKeyword":"尺度效应"}],"language":"zh","publisherId":"gfzclkxygc201502025","title":"等规聚丙烯微注<span style=\"color:red\">塑制品</span>的力学性能","volume":"31","year":"2015"},{"abstractinfo":"将短纤维增强注<span style=\"color:red\">塑制品</span>看作多层板并分析了注<span style=\"color:red\">塑制品</span>的有效弹性性能.采用Tandon-Weng模型计算了单取向短纤维增强复合材料的弹性性能,采用取向平均法计算了具有任意平面取向的单层板材料弹性常数,运用层合板理论建立了短纤维增强注塑材料的有效弹性模量计算模型.测定了特制试样中的纤维取向分布,计算了有效弹性模量,并与实验结果对比证明这种方法是有效的.","authors":[{"authorName":"刘保臣","id":"6c671789-77ae-45b5-a994-b7116a68905e","originalAuthorName":"刘保臣"},{"authorName":"申长雨","id":"303b93b9-fb25-4fa9-ab3a-99f47c5e07f4","originalAuthorName":"申长雨"},{"authorName":"刘春太","id":"fc8366d0-5e20-45c4-ae22-f59dfa36f371","originalAuthorName":"刘春太"},{"authorName":"上官林建","id":"842c47a2-b7eb-40b1-a436-5140903df434","originalAuthorName":"上官林建"}],"doi":"","fpage":"80","id":"1b188d38-5141-40a9-941e-33b207838166","issue":"14","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"19b1afee-5e27-4219-8468-8194d81e0729","keyword":"纤维取向","originalKeyword":"纤维取向"},{"id":"0adbd00f-701b-4b3c-9ade-493027d045f4","keyword":"短纤维增强复合材料","originalKeyword":"短纤维增强复合材料"},{"id":"afac30c6-ec21-4981-90bd-06743f893254","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"bd0a6b88-2330-4bb4-b5db-deca46ffbefc","keyword":"注射成型","originalKeyword":"注射成型"}],"language":"zh","publisherId":"cldb200914023","title":"短纤维增强注<span style=\"color:red\">塑制品</span>的力学性能分析","volume":"23","year":"2009"},{"abstractinfo":"注<span style=\"color:red\">塑制品</span>成型凝固时对型芯产生的包紧力大小及其分布,是影响<span style=\"color:red\">制品</span>脱模变形或开裂的主要因素.以简单矩形盒状<span style=\"color:red\">制品</span>为对象,设计制造了单型腔直浇口模具,并对高密度聚乙烯(HDPE)、聚丙烯(PP)及丙烯腈-丁二烯-苯乙烯共聚物(ABS)材料,进行了不同工艺参数作用下的单因素成型实验及<span style=\"color:red\">制品</span>脱模力的测量,研究了工艺参数变化对<span style=\"color:red\">制品</span>包紧力产生的作用机理及对脱模力的影响关系.结果表明,<span style=\"color:red\">制品</span>凝固时其内部分子的结晶、收缩及不平衡应力等,是影响<span style=\"color:red\">制品</span>包紧力大小的主要因素.而提高脱模温度,会使<span style=\"color:red\">制品</span>对型芯的包紧力明显减小,脱模力随之减小.","authors":[{"authorName":"于同敏","id":"a7c3173c-2d69-46bc-a479-a85a54b0e941","originalAuthorName":"于同敏"},{"authorName":"焦旭","id":"8a7b8cb9-98fb-4c53-82e5-17bb3de2ec3b","originalAuthorName":"焦旭"},{"authorName":"武永强","id":"10805950-583a-4ce4-8370-a301e27e88ef","originalAuthorName":"武永强"}],"doi":"","fpage":"96","id":"0d64972e-114f-4fc6-af8a-e3b2f4cbf1f6","issue":"6","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":"48537cfb-1cef-4e1e-a2df-5f7cf02298cc","keyword":"盒状<span style=\"color:red\">制品</span>","originalKeyword":"盒状制品"},{"id":"8119c052-c431-4a25-900b-fe5100928783","keyword":"工艺参数","originalKeyword":"工艺参数"},{"id":"8f798151-8e4a-4f36-8e4f-959b0b7d06d7","keyword":"注塑成型实验","originalKeyword":"注塑成型实验"},{"id":"f11f05fc-1836-4c36-b695-2692118c5cfd","keyword":"脱模力测量","originalKeyword":"脱模力测量"}],"language":"zh","publisherId":"gfzclkxygc201406021","title":"工艺参数对注<span style=\"color:red\">塑制品</span>包紧力的影响及脱模力测量","volume":"30","year":"2014"},{"abstractinfo":"对注射成型中四种不同的v/p(射速/压力)转压方式的工艺性能进行了研究,以<span style=\"color:red\">制品</span>质量作为验证参数,同时考虑了模具温度的变化.研究发现,注<span style=\"color:red\">塑制品</span>质量重复精度的提高除了受到转压方式的影响还同相应转压方式下的工艺参数设定有关;<span style=\"color:red\">制品</span>质量的变化受模具温度的影响,常规转压方式下,<span style=\"color:red\">制品</span>质量随模具温度升高而降低,而模腔熔体温度转压方式下,<span style=\"color:red\">制品</span>质量反而有升高;模腔熔体温度转压方式可对<span style=\"color:red\">制品</span>质量进行控制;研究结果表明,以熔体温度为信号的转压控制方式不但具有可行性,甚至还可提高成型<span style=\"color:red\">制品</span>的质量重复精度.","authors":[{"authorName":"王建","id":"690cd26f-0e17-42bf-b789-bb6b8965e57d","originalAuthorName":"王建"},{"authorName":"谢鹏程","id":"34f406bd-792c-4586-a188-7508f45583f7","originalAuthorName":"谢鹏程"},{"authorName":"丁玉梅","id":"3cd9c808-431a-4d59-82b0-299a2201a2bd","originalAuthorName":"丁玉梅"},{"authorName":"杨卫民","id":"870d00c5-fc9a-467d-878e-4f4124d52b60","originalAuthorName":"杨卫民"}],"doi":"","fpage":"110","id":"d5a9992a-f6c1-430d-a61b-ccdc9b6f6a1b","issue":"6","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":"609175f1-3de7-4de3-a50c-0807ded8b916","keyword":"注射成型","originalKeyword":"注射成型"},{"id":"27c50710-57c0-42d7-b020-303d66670591","keyword":"射速/压力转压方式","originalKeyword":"射速/压力转压方式"},{"id":"1be2b5e7-6fce-4298-bf56-13701a703301","keyword":"模具温度","originalKeyword":"模具温度"},{"id":"37baa0e3-0f8c-43ff-977a-9734c3d3fe24","keyword":"质量重复精度","originalKeyword":"质量重复精度"}],"language":"zh","publisherId":"gfzclkxygc201106030","title":"v/p转压方式对注<span style=\"color:red\">塑制品</span>质量重复精度的影响","volume":"27","year":"2011"},{"abstractinfo":"文中结合计算机辅助工程(CAE)及Taguchi实验设计(DOE)技术研究了玻纤含量和工艺参数对玻纤增强聚丙烯注<span style=\"color:red\">塑制品</span>各向异性收缩的影响.基于Taguchi DOE方法采用L18(36)正交矩阵进行了实验以优化<span style=\"color:red\">制品</span>的收缩,并研究了各个参数对<span style=\"color:red\">制品</span>收缩的影响程度.对于主实验中所选因素,纤维含量、熔体温度和保压压力对玻纤增强聚丙烯注<span style=\"color:red\">塑制品</span>各向异性收缩的影响较大.","authors":[{"authorName":"王利霞","id":"53688498-6349-4305-b54c-0a233f171e67","originalAuthorName":"王利霞"},{"authorName":"李燕","id":"ea81091e-39bb-4e29-82e6-c5a7575c0637","originalAuthorName":"李燕"},{"authorName":"庄卫国","id":"afda97b4-c991-496a-9ac1-c79f9d4c5d27","originalAuthorName":"庄卫国"}],"doi":"","fpage":"135","id":"c57895b1-350c-48e5-a859-7449be77b921","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":"8cd7ad0b-2137-489b-a8ab-3ba823078bf0","keyword":"注塑成型","originalKeyword":"注塑成型"},{"id":"c1497691-218b-44a1-9b2a-8fc4ac543ae0","keyword":"玻纤增强聚丙烯","originalKeyword":"玻纤增强聚丙烯"},{"id":"cf4802a3-46ad-4bbf-b41d-ad797032c203","keyword":"Taguchi DOE","originalKeyword":"Taguchi DOE"},{"id":"33b15292-3804-4e62-b40d-f70e3c6b72cd","keyword":"收缩","originalKeyword":"收缩"}],"language":"zh","publisherId":"gfzclkxygc200909037","title":"注塑工艺和玻纤含量对玻纤增强PP注<span style=\"color:red\">塑制品</span>收缩的影响","volume":"25","year":"2009"}],"totalpage":128,"totalrecord":1280}