{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"采用电磁离心铸造方法制备了1Cr18Ni9Ti不锈钢管坯.在电磁搅拌作用下,管坯铸态微观组织被细化,一次枝晶间距为40μm,与普通离心铸造相比减小70%;管坯的室温屈服强度为274 MPa、延伸率为77%,分别比普通离心铸造管坯提高23%和28%.实验结果表明:电磁离心铸造可明显提高管坯的<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span><span style=\"color:red\">性能</span>,利用电磁离心管坯可直接进行冷轧1Cr18Ni9Ti不锈钢无缝薄壁管,实验得到的最大减薄率大于91.4%.","authors":[{"authorName":"林刚","id":"b698f3d3-136b-4e82-8ee0-75f5c8f483d7","originalAuthorName":"林刚"},{"authorName":"杨院生","id":"18f2d389-f510-4641-bdb4-6c23b3475b75","originalAuthorName":"杨院生"},{"authorName":"花福安","id":"8a877361-b861-4c2b-90eb-b0572a473e27","originalAuthorName":"花福安"},{"authorName":"郭大勇","id":"0ed72990-38e2-4560-9977-1537149adef1","originalAuthorName":"郭大勇"},{"authorName":"胡壮麒","id":"1150cf0a-8248-4b66-93d2-ec6bdacf2389","originalAuthorName":"胡壮麒"}],"doi":"10.3321/j.issn:0412-1961.2003.12.001","fpage":"1233","id":"8f3ffdbc-0356-4731-8af2-6202af97d07e","issue":"12","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"bfa64a6a-7a23-4e17-8885-e8c86dda8fc6","keyword":"电磁离心铸造","originalKeyword":"电磁离心铸造"},{"id":"78bd6f9d-003a-4131-9aa0-cd0836578ef6","keyword":"不锈钢","originalKeyword":"不锈钢"},{"id":"a9a0a79a-01af-4728-8f55-4dfd5971f800","keyword":"冷轧","originalKeyword":"冷轧"},{"id":"be76b57e-f818-4802-9f32-749c338da08d","keyword":"一次枝晶间距","originalKeyword":"一次枝晶间距"},{"id":"4f868221-c610-43ac-9075-ccfa17c7ea80","keyword":"<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span><span style=\"color:red\">性能</span>","originalKeyword":"塑性加工性能"}],"language":"zh","publisherId":"jsxb200312001","title":"电磁离心1Cr18Ni9Ti不锈钢的凝固组织与变形<span style=\"color:red\">性能</span>","volume":"39","year":"2003"},{"abstractinfo":"将铝板<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>成半球孔层金属结构薄层, 以此为基本单元按一定方式连接形成球形孔多孔金属, 研究了孔结构对球形孔多孔金属<span style=\"color:red\">性能</span>的影响. 结果表明, 平板层相连的球形孔结构, 使其强度高于同样条件下堆积的空心金属球结构. 这种新型球形孔多孔金属的强度较高, 能够有效地吸收能量, 铝板的厚度和孔隙率对其压缩和能量吸能<span style=\"color:red\">性能</span>有明显的影响.","authors":[{"authorName":"施国栋何德坪何思渊丁龙","id":"11d5e00d-753d-45ec-bc27-441e67c05c46","originalAuthorName":"施国栋何德坪何思渊丁龙"}],"categoryName":"|","doi":"","fpage":"143","id":"59c89261-f63d-48c9-af66-9d37e071c253","issue":"2","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":"abd83dec-69cd-48b3-b605-cdae39329869","keyword":"金属材料","originalKeyword":"金属材料"},{"id":"8f16f3dd-187d-460e-b81d-5e8acda5a5b2","keyword":"punch","originalKeyword":"punch"},{"id":"8a317489-0663-477e-8618-2ae0f8f561ca","keyword":"porous metal","originalKeyword":"porous metal"},{"id":"759ff54b-a73b-4b74-95b6-a36e15f2372f","keyword":"porosity","originalKeyword":"porosity"},{"id":"4911e1ab-08e2-4441-a08f-debcadfd2bd4","keyword":"compression and energy absorption","originalKeyword":"compression and energy absorption"},{"id":"afcbdd7b-3144-446d-a393-d027e9d1523a","keyword":"spherical pore","originalKeyword":"spherical pore"}],"language":"zh","publisherId":"1005-3093_2009_2_15","title":"新型<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>制备球形孔多孔金属及其<span style=\"color:red\">性能</span>","volume":"23","year":"2009"},{"abstractinfo":"将铝板<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>成半球孔层金属结构薄层,以此为基本单元按一定方式连接形成球形孔多孔金属,研究了孔结构对球形孔多孔金属<span style=\"color:red\">性能</span>的影响.结果表明,平板层相连的球形孔结构,使其强度高于同样条件下堆积的空心金属球结构.这种新型球形孔多孔金属的强度较高,能够有效地吸收能量,铝板的厚度和孔隙率对其压缩和能量吸能<span style=\"color:red\">性能</span>有明显的影响.","authors":[{"authorName":"施国栋","id":"ff92230d-e36d-4502-b72c-fa1ff8165c8c","originalAuthorName":"施国栋"},{"authorName":"何德坪","id":"ca559085-1f79-4e74-a2b5-888951024378","originalAuthorName":"何德坪"},{"authorName":"何思渊","id":"79ef0f2a-bc43-4288-b92b-232a8ad1a02f","originalAuthorName":"何思渊"},{"authorName":"丁龙","id":"de5c4d68-ace9-43fa-99cd-10e97abf7efc","originalAuthorName":"丁龙"}],"doi":"10.3321/j.issn:1005-3093.2009.02.007","fpage":"143","id":"93b3e2e6-4da0-43d8-a397-3dc3acb9efeb","issue":"2","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":"8d6be924-25de-4c20-935a-f331fd15d81b","keyword":"金属材料","originalKeyword":"金属材料"},{"id":"57ce9db2-4d4b-4ff4-9b17-ca3a9a7be876","keyword":"冲压","originalKeyword":"冲压"},{"id":"6a423eb6-5859-4f1a-893b-12d644c05faa","keyword":"多孔金属","originalKeyword":"多孔金属"},{"id":"4679918d-c122-4d5b-8901-aa82b57855a8","keyword":"孔隙率","originalKeyword":"孔隙率"},{"id":"266dab8a-3d0e-475d-a623-1b52b045c5c9","keyword":"压缩吸能","originalKeyword":"压缩吸能"},{"id":"8f7b002a-3826-43d0-89b8-da7430937c2f","keyword":"球形孔","originalKeyword":"球形孔"}],"language":"zh","publisherId":"clyjxb200902007","title":"新型<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>制备球形孔多孔金属及其<span style=\"color:red\">性能</span>","volume":"23","year":"2009"},{"abstractinfo":"介绍了镁合金的<span style=\"color:red\">性能</span>及现状.综述了难变形镁合金的<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>新技术,包括氢化处理技术、电<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>技术及大<span style=\"color:red\">塑性</span>变形<span style=\"color:red\">加工</span>技术.对这几种新<span style=\"color:red\">加工</span>技术的特点及发展现状进行了详细介绍,最后,总结了这些技术针对镁合金<span style=\"color:red\">加工</span>的应用前景.","authors":[{"authorName":"马光","id":"6ccd1183-fab1-4a75-bf58-1a7c5ef6d785","originalAuthorName":"马光"},{"authorName":"孙晓亮","id":"924f98ed-7cd8-4a21-a8e2-7fdda19d3885","originalAuthorName":"孙晓亮"},{"authorName":"刘啸锋","id":"7d527990-3548-452e-aaa5-6e974db877a3","originalAuthorName":"刘啸锋"},{"authorName":"郑晶","id":"ef94398f-0441-4c11-802d-2cb68902fa40","originalAuthorName":"郑晶"},{"authorName":"李银娥","id":"af23ce6d-5414-47af-a3dd-31c5fbb70103","originalAuthorName":"李银娥"}],"doi":"10.3969/j.issn.1009-9964.2009.06.004","fpage":"11","id":"768a353c-0c32-44f0-a887-ccce9f927387","issue":"6","journal":{"abbrevTitle":"TGYJZ","coverImgSrc":"journal/img/cover/TGYJZ.jpg","id":"60","issnPpub":"1009-9964","publisherId":"TGYJZ","title":"钛工业进展"},"keywords":[{"id":"1c17d954-b173-400a-ab26-041f00442bf4","keyword":"镁合金","originalKeyword":"镁合金"},{"id":"5785f3aa-9fa9-4333-b5b6-e0f89e056965","keyword":"氢化处理","originalKeyword":"氢化处理"},{"id":"4367e298-ebc9-475f-a431-327084210958","keyword":"电<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>","originalKeyword":"电塑性加工"},{"id":"f1aed6f2-c532-4f68-b473-9fde6de2c801","keyword":"大<span style=\"color:red\">塑性</span>变形","originalKeyword":"大塑性变形"}],"language":"zh","publisherId":"tgyjz200906004","title":"镁合金<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>新工艺","volume":"26","year":"2009"},{"abstractinfo":"脆性材料以其特殊的电、化学、物理<span style=\"color:red\">性能</span>在电子、光学等产业得到广泛的应用，但由于其硬度高、脆性大，很难满足<span style=\"color:red\">加工</span>要求。<span style=\"color:red\">塑性</span>域<span style=\"color:red\">加工</span>作为目前一种行之有效的方式，得到了广泛研究。振动条件下的<span style=\"color:red\">加工</span>可以显著扩大<span style=\"color:red\">塑性</span>域范围，增加临界切削深度。对<span style=\"color:red\">塑性</span>域<span style=\"color:red\">加工</span>中的脆塑转变机理、振动条件下的<span style=\"color:red\">加工</span>过程进行运动学分析，并比较振动条件下<span style=\"color:red\">加工</span>与普通<span style=\"color:red\">加工</span>在表面粗糙度、刀具磨损、临界切削深度、最小切削深度方面的区别，最后分析了振动条件下<span style=\"color:red\">塑性</span>域<span style=\"color:red\">加工</span>需要满足的条件。","authors":[{"authorName":"李梓","id":"23ffd641-31db-4151-80ab-1efd04eca67a","originalAuthorName":"李梓"},{"authorName":"李淑娟","id":"6cd73fc9-141e-49f2-a014-4024d79b7112","originalAuthorName":"李淑娟"},{"authorName":"麻高领","id":"03105249-be97-4eb2-8314-7a52a7e884fa","originalAuthorName":"麻高领"}],"doi":"","fpage":"124","id":"adf7c8c2-328a-4603-9ecd-44123807455a","issue":"2","journal":{"abbrevTitle":"BQCLKXYGC","coverImgSrc":"journal/img/cover/BQCLKXYGC.jpg","id":"4","issnPpub":"1004-244X","publisherId":"BQCLKXYGC","title":"兵器材料科学与工程   "},"keywords":[{"id":"aedececa-de91-487b-9d1b-72cd648eb7ed","keyword":"脆性材料","originalKeyword":"脆性材料"},{"id":"a32a811a-15e0-4c9f-9d6a-7062aa15389b","keyword":"<span style=\"color:red\">塑性</span>域<span style=\"color:red\">加工</span>","originalKeyword":"塑性域加工"},{"id":"bca15339-9904-45b1-b70a-f911cd9b1ece","keyword":"塑脆转变","originalKeyword":"塑脆转变"},{"id":"b772dab8-0c78-40f7-af6e-a8c6f7baaf9f","keyword":"临界切削深度","originalKeyword":"临界切削深度"},{"id":"d4e54b4d-c179-4c40-825c-892a487e0e00","keyword":"振动条件下的<span style=\"color:red\">加工</span>","originalKeyword":"振动条件下的加工"}],"language":"zh","publisherId":"bqclkxygc201502031","title":"脆性材料<span style=\"color:red\">塑性</span>域超声<span style=\"color:red\">加工</span>综述","volume":"","year":"2015"},{"abstractinfo":"短碳纤维增强铝基复合材料可以经<span style=\"color:red\">塑性</span>变形<span style=\"color:red\">加工</span>成各种形状的零件,但<span style=\"color:red\">塑性</span>变形过程对材料的组织与<span style=\"color:red\">性能</span>有着重要影响.本工作用挤压浸渗法获得的Csf/Al复合材料为毛坯,通过挤压的方法,研究了变形温度、变形量等对材料组织与<span style=\"color:red\">性能</span>的影响.结果表明,一定量的<span style=\"color:red\">塑性</span>变形可以弥合浸渗不完全留下的微小空隙,并使纤维成方向性排列,复合材料的<span style=\"color:red\">性能</span>得到提高.但大变形会使纤维断裂,影响增强效果.变形温度越高,对复合材料<span style=\"color:red\">性能</span>越有利.","authors":[{"authorName":"张广安","id":"9f13fac5-12b7-4943-b430-44962adbc4a9","originalAuthorName":"张广安"},{"authorName":"罗守靖","id":"76686308-c83c-4980-a50d-c8c582d9d4c4","originalAuthorName":"罗守靖"},{"authorName":"腾东东","id":"9fd533c7-0beb-4a07-bded-a128274caae7","originalAuthorName":"腾东东"}],"doi":"10.3969/j.issn.1001-4381.2003.06.009","fpage":"32","id":"70f955d4-02db-4b02-b625-cfe236fd2482","issue":"6","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"422246cf-df26-4680-b107-298442c83142","keyword":"<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>","originalKeyword":"塑性加工"},{"id":"5cf8cb87-e0ec-42b5-8622-ab2a11359887","keyword":"碳铝复合材料","originalKeyword":"碳铝复合材料"},{"id":"25f33378-fa66-4bfc-b4af-772601dbcae8","keyword":"组织与<span style=\"color:red\">性能</span>","originalKeyword":"组织与性能"}],"language":"zh","publisherId":"clgc200306009","title":"<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>对Csf/Al复合材料组织与<span style=\"color:red\">性能</span>的影响","volume":"","year":"2003"},{"abstractinfo":"研究了电<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>技术在冷拔钢丝领域的应用,探讨了电<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>改变冷<span style=\"color:red\">加工</span>材料<span style=\"color:red\">性能</span>的机制.试验结果表明,电<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>技术,可有效地降低钢丝生产中的拉拔力,降低钢丝的强度,提高<span style=\"color:red\">塑性</span>.","authors":[{"authorName":"唐国翌","id":"0a3fca8b-ff03-4423-99dc-49c3813960fa","originalAuthorName":"唐国翌"},{"authorName":"郑明新","id":"8d835d1c-4739-422e-a35d-f9138fe987c8","originalAuthorName":"郑明新"},{"authorName":"朱永华","id":"4a09415b-19ae-44c8-8aaf-6ae309260763","originalAuthorName":"朱永华"},{"authorName":"张杰","id":"95be6ecb-151b-43c2-8260-dddf4727136b","originalAuthorName":"张杰"},{"authorName":"方威","id":"ec2f5514-d4f7-41fc-b2db-b9757ae16402","originalAuthorName":"方威"},{"authorName":"李寣","id":"890d3b49-a114-4c3a-a990-85d894bb514f","originalAuthorName":"李寣"}],"doi":"","fpage":"35","id":"35f00027-311d-49f9-a7c3-5e7a72ff129f","issue":"9","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"48227572-e4eb-4795-a8e9-d233c1a5ce4b","keyword":"电<span style=\"color:red\">塑性</span>效应","originalKeyword":"电塑性效应"},{"id":"3292a8f5-03d1-48da-8ceb-275880cb9ede","keyword":"钢丝","originalKeyword":"钢丝"},{"id":"5e5f6d70-daf7-44ce-bb0f-b5f400fbb495","keyword":"冷拔","originalKeyword":"冷拔"}],"language":"zh","publisherId":"gt199809009","title":"电<span style=\"color:red\">塑性</span><span style=\"color:red\">加工</span>技术及其工程应用","volume":"33","year":"1998"},{"abstractinfo":"以三苯二硫醚二酐(PTPODA)为二酐单体，4,4'-二氨基二苯醚(ODA)为二胺单体，邻苯二甲酸酐(PA)为封端剂，采用不同二酐和二胺比例通过一步法聚合制备了不同分子量的热<span style=\"color:red\">塑性</span>聚酰亚胺，其比浓对数黏度分别为0.41 dL/g、0.45 dL/g、0.53 dL/g，并对其热<span style=\"color:red\">性能</span>、溶解性、熔体<span style=\"color:red\">性能</span>、力学<span style=\"color:red\">性能</span>进行了研究。结果表明：该聚酰亚胺的玻璃化转变温度(Tg)为205~207℃；空气中5%热分解温度为514~531℃，氮气中5%热分解温度在519~538℃之间；拉伸强度超过64 MPa，拉伸模量高于1.9 GPa，断裂伸长率高于4%；在常规有机溶剂NMP、DMAc等中有良好的溶解性；320℃时的熔融指数在6.21~9.74 g/10 min之间，熔体<span style=\"color:red\">加工</span>性较好。","authors":[{"authorName":"魏志龙","id":"8b50e4f4-71db-4c31-98fc-772d23d78825","originalAuthorName":"魏志龙"},{"authorName":"岳红","id":"24c1a5d0-0191-498d-8cd3-4833bff179f9","originalAuthorName":"岳红"},{"authorName":"陈国飞","id":"ffddd416-dcdf-4ff1-901e-047695b49519","originalAuthorName":"陈国飞"},{"authorName":"张鸿飞","id":"89f1b347-f463-4ff3-805a-af54c3de7686","originalAuthorName":"张鸿飞"},{"authorName":"刘江涛","id":"228215f5-4b99-4390-ab35-41e1a2d1fad0","originalAuthorName":"刘江涛"},{"authorName":"方省众","id":"edc40c05-f4eb-4bdf-84ab-eced7d5a9b9e","originalAuthorName":"方省众"}],"doi":"","fpage":"10","id":"4302a76a-d3b0-462e-9dd0-a6751a5fe2f6","issue":"5","journal":{"abbrevTitle":"JYCL","coverImgSrc":"journal/img/cover/JYCL.jpg","id":"50","issnPpub":"1009-9239","publisherId":"JYCL","title":"绝缘材料"},"keywords":[{"id":"686df5d6-d265-49a5-a8e3-34d816f64ef4","keyword":"热<span style=\"color:red\">塑性</span>聚酰亚胺","originalKeyword":"热塑性聚酰亚胺"},{"id":"2a75c23a-6949-4788-ad77-42126fc53074","keyword":"熔体<span style=\"color:red\">加工</span>性","originalKeyword":"熔体加工性"},{"id":"56d33b49-6e17-45c6-9dfc-cebe220d680d","keyword":"溶解性","originalKeyword":"溶解性"},{"id":"50e61343-a6f8-4a8a-a500-cc8f76ab8071","keyword":"耐热性","originalKeyword":"耐热性"}],"language":"zh","publisherId":"jycltx201505004","title":"新型易<span style=\"color:red\">加工</span>热<span style=\"color:red\">塑性</span>聚酰亚胺的合成及<span style=\"color:red\">性能</span>研究","volume":"","year":"2015"},{"abstractinfo":"先通过甘油对淀粉进行塑化制备热<span style=\"color:red\">塑性</span>淀粉(TPS),然后以马来酸酐接枝聚丙烯(MA-g-PP)作为增容剂将聚丙烯(PP)与 TPS 共混,制成 TPS/PP 复合材料。通过电子拉力机、热重法、转矩流变仪、挤出毛细管流变仪以及熔融指数仪,研究了不同含量的MA-g-PP 对 TPS/PP <span style=\"color:red\">性能</span>的影响。结果表明,MA-g-PP 的添加可有效提高材料的力学和<span style=\"color:red\">加工</span><span style=\"color:red\">性能</span>,综合生产成本和增容效果考虑,当 MA-g-PP 的添加量为 PP/TPS 总量的4％(质量分数)时,材料具有较高的力学<span style=\"color:red\">性能</span>和较佳的<span style=\"color:red\">加工</span><span style=\"color:red\">性能</span>。","authors":[{"authorName":"王礼建","id":"3ecb85e5-2e37-44fb-9e11-cc49d85c02a6","originalAuthorName":"王礼建"},{"authorName":"董亚强","id":"91c71dbe-7a9a-4fd2-9456-d3ccaa78bdef","originalAuthorName":"董亚强"},{"authorName":"杨政","id":"e8744e5c-1e5b-4b49-879b-399c206f3fbc","originalAuthorName":"杨政"},{"authorName":"郭斌","id":"3b3eb3d6-61fc-4d23-a600-5293767756d6","originalAuthorName":"郭斌"},{"authorName":"李本刚","id":"3ffafb5c-2849-40a5-9956-0d4c0f3b0870","originalAuthorName":"李本刚"},{"authorName":"李盘欣","id":"1ee047ca-2ca1-4e37-9d0e-49ea0e8a9b3c","originalAuthorName":"李盘欣"}],"doi":"10.3969/j.issn.1001-9731.2015.增刊(Ⅰ).012","fpage":"53","id":"4c1b3a2e-d32f-444f-969f-050097b83907","issue":"z1","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"cb95f1f8-f360-440e-afe5-7667608760f9","keyword":"增容剂","originalKeyword":"增容剂"},{"id":"0bb910d0-717f-402a-92bf-211b2aa84519","keyword":"聚丙烯","originalKeyword":"聚丙烯"},{"id":"5a18c2af-5a03-473c-93ed-488a97e79180","keyword":"增强","originalKeyword":"增强"},{"id":"d5ac7175-860a-40a9-8a06-2ba4e9bd60ab","keyword":"热<span style=\"color:red\">塑性</span>淀粉","originalKeyword":"热塑性淀粉"}],"language":"zh","publisherId":"gncl2015z1012","title":"增容剂对热<span style=\"color:red\">塑性</span>淀粉/聚丙烯复合材料的力学及流变<span style=\"color:red\">加工</span><span style=\"color:red\">性能</span>的影响?","volume":"","year":"2015"},{"abstractinfo":"揭示了一种热<span style=\"color:red\">塑性</span>组合物，该组合物包含：至少一种热<span style=\"color:red\">塑性</span>聚合物的连续相；非聚合前体，所述前体能够聚合，形成分散在所述热<span style=\"color:red\">塑性</span>聚合物中的聚合的强化相。所述前体在分散到所述热<span style=\"color:red\">塑性</span>聚合物的连续相中之后发生聚合。从而增大了所述热<span style=\"color:red\">塑性</span>聚合物的挠曲模量。还揭示了所述组合物的制备和使用方法。","authors":[],"doi":"","fpage":"95","id":"b00fe6e3-be89-4411-9197-d9f39a5d4ad1","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":"8d6f350e-f344-420f-85af-fd0072350f3b","keyword":"热<span style=\"color:red\">塑性</span>组合物","originalKeyword":"热塑性组合物"},{"id":"90980b7d-0cf6-4297-95f0-23bf8d261b70","keyword":"强化相","originalKeyword":"强化相"},{"id":"26526d27-43d3-4395-b1dd-ca584f958fbe","keyword":"<span style=\"color:red\">加工</span><span style=\"color:red\">性能</span>","originalKeyword":"加工性能"},{"id":"f5e4ddc4-0794-4bdf-b46b-c8d7b2d5d0d9","keyword":"热<span style=\"color:red\">塑性</span>聚合物","originalKeyword":"热塑性聚合物"},{"id":"4de210d2-9da0-44bf-aadb-71a49dbf8c30","keyword":"挠曲模量","originalKeyword":"挠曲模量"},{"id":"ce26ecc3-4d1e-419d-bc83-d4c817d87199","keyword":"连续相","originalKeyword":"连续相"},{"id":"9c284ba1-1e45-476f-a64d-7c73d42d6974","keyword":"前体","originalKeyword":"前体"},{"id":"4fa9f75b-bd98-48c5-b470-fa56701cb5b6","keyword":"分散","originalKeyword":"分散"}],"language":"zh","publisherId":"gfzclkxygc201202025","title":"具有提高的<span style=\"color:red\">加工</span><span style=\"color:red\">性能</span>的强化热<span style=\"color:red\">塑性</span>组合物","volume":"28","year":"2012"}],"totalpage":9261,"totalrecord":92608}