{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"由于鞍钢转炉钢渣存在体积安定性不良等问题,严重制约了钢渣的再利用途径和范围.采用扫描电子显微镜的X射线能谱仪等手段观察了鞍钢转炉渣的矿物形貌,测定了矿物的元素成分,并对不同时期转炉渣中f-CaO与f-MgO的含量进行化学分析,以明确f-CaO、RO相和f-MgO等对钢渣安定性的影响规律.结果表明:1)鞍钢转炉钢渣中主要矿物相为C2S、铁铝钙、镁铁相固溶体和少量C3S、f-CaO与f-MgO;2)鞍钢转炉渣中RO相的主要组织为镁铁相,质量分数为10~20%,MgO/FeO的典型比例约为1:2;3)鞍钢转炉渣f-CaO质量分数为2.08%~7.79%,f-MgO质量分数为0.16%~0.41%;4)微观形貌和化学分析结果均证明鞍钢转炉钢渣安定性的主要影响因素为f-CaO含量;5)游离氧化镁的单相组织极少,对转炉渣的安定性影响主要取决于RO相.","authors":[{"authorName":"王向锋","id":"efe7b468-f8cc-4e09-b0cb-1bd08f46b39d","originalAuthorName":"王向锋"},{"authorName":"张新义","id":"49d55ed4-b736-4db1-a9ff-4242bb7d2450","originalAuthorName":"张新义"},{"authorName":"于淑娟","id":"ac1d54ef-b424-4eb9-b6e9-f4ea361dd90a","originalAuthorName":"于淑娟"},{"authorName":"侯洪宇","id":"d5554f75-baa0-41d8-91ed-5003d0868938","originalAuthorName":"侯洪宇"},{"authorName":"杨大正","id":"8c758d77-efc6-4854-92e2-03fbc7a11558","originalAuthorName":"杨大正"},{"authorName":"王再义","id":"574d958e-04f9-4feb-a4af-8c0758468e40","originalAuthorName":"王再义"}],"doi":"","fpage":"98","id":"c2704857-373c-494f-90e3-5de37e9e9760","issue":"6","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"7d1323ba-fda2-483f-8466-c1e482246765","keyword":"钢渣","originalKeyword":"钢渣"},{"id":"720c0b56-13fb-4576-af49-fe6b63cc78e5","keyword":"矿物相","originalKeyword":"矿物相"},{"id":"69ba8bb5-130a-4bfd-92a5-ff0233f11632","keyword":"安定性","originalKeyword":"安定性"}],"language":"zh","publisherId":"gt201006021","title":"影响鞍钢转炉渣安定性的矿物相研究","volume":"45","year":"2010"},{"abstractinfo":"将CrO3粉与Al粉按1:2(物质的量比)配料,加入适量的稀释剂Al2O3粉、添加剂NaF粉和结合剂混匀后,压入高炉风口的型腔内,在空气中燃烧合成了风口的陶瓷涂层.利用XRD、SEM和EDS分析了该涂层材料的物相与显微结构,并结合该材料的性能指标分析了其用作风口涂层的可行性.结果表明:燃烧合成陶瓷涂层材料的主要物相是Cr2N、α-Al2O3和Cr,其耐火度>1800℃,常温耐压强度58.8 MPa,体积密度1.36 g·cm-3,显气孔率57%,600℃时的热导率0.796W·(m·K)-1.因此,该材料耐高温,耐磨损,抗渣铁侵蚀,用其作高炉风口的陶瓷涂层不但可以有效延长风口的寿命,而且还有很好的保温、节能效果.","authors":[{"authorName":"杨大正","id":"90fdf8ea-a615-43d0-be1c-32055c38f5e5","originalAuthorName":"杨大正"},{"authorName":"张跃","id":"ffd91670-9ec6-4fb7-8720-67433a43df65","originalAuthorName":"张跃"},{"authorName":"于淑娟","id":"9c67fee7-7b03-4c10-8f10-066122b67afb","originalAuthorName":"于淑娟"},{"authorName":"王再义","id":"e65fe0eb-5072-4042-b1da-25e4bac012be","originalAuthorName":"王再义"},{"authorName":"邢本策","id":"58e24965-170f-42c3-8857-cd72641b2437","originalAuthorName":"邢本策"},{"authorName":"胡春娥","id":"9017defc-eac5-4b85-87a6-42b3efdf003d","originalAuthorName":"胡春娥"},{"authorName":"佟晓军","id":"09de96ec-ae03-4fa1-bed4-71680c727be8","originalAuthorName":"佟晓军"}],"doi":"10.3969/j.issn.1001-1935.2005.05.009","fpage":"351","id":"a860c6b8-1420-4c0c-b61f-c8f04db8b373","issue":"5","journal":{"abbrevTitle":"NHCL","coverImgSrc":"journal/img/cover/NHCL.jpg","id":"55","issnPpub":"1001-1935","publisherId":"NHCL","title":"耐火材料 "},"keywords":[{"id":"462750e7-6507-4e8a-bc49-f21ba1ed539b","keyword":"燃烧合成","originalKeyword":"燃烧合成"},{"id":"eab2f274-5798-480a-ad7e-63a45470e1eb","keyword":"高炉风口","originalKeyword":"高炉风口"},{"id":"63688f4b-7fa2-405c-a476-064e22b8281c","keyword":"陶瓷涂层","originalKeyword":"陶瓷涂层"}],"language":"zh","publisherId":"nhcl200505009","title":"燃烧合成高炉风口陶瓷涂层的研究","volume":"39","year":"2005"},{"abstractinfo":"通过烧结杯烧结试验研究,获得了以反浮选赤铁细精矿为主要铁料生产高质量烧结矿的生产工艺参数及合理配矿方案.采用控制混合料中氧化亚铁含量进行配矿,保证生石灰用量,改善料层透气性和氧化性气氛等措施,可以获得以铁酸钙为主要粘结相的烧结矿.在高碱度烧结条件下,改善了自产精矿烧结温度高、烧结性差的烧结特性,也解决了自产精矿\"泥\"和\"粘\"带来的配料操作及混匀、造球等方面的技术问题.在采用低硅细赤铁精矿生产高碱度烧结矿实践中取得了良好效果.","authors":[{"authorName":"于淑娟","id":"9d6a6a35-6204-47be-afe4-bbffd900ea71","originalAuthorName":"于淑娟"},{"authorName":"王常秋","id":"5b81a536-109a-4e8a-a929-9b635027c1b1","originalAuthorName":"王常秋"},{"authorName":"李荣波","id":"091ba7a4-fbdc-4303-bc31-9b2229816abb","originalAuthorName":"李荣波"},{"authorName":"吴铿","id":"a9c235cd-ecd7-4206-af5a-9fdb794a2049","originalAuthorName":"吴铿"},{"authorName":"郑涛","id":"db894cfd-090e-43c8-830c-4d9e1c8e9395","originalAuthorName":"郑涛"}],"doi":"","fpage":"7","id":"3117e66c-bdd4-4cef-a489-fa00eb31f5a5","issue":"7","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"96dd90b9-c390-4bb2-bde3-ba419d1556c4","keyword":"赤铁精矿烧结","originalKeyword":"赤铁精矿烧结"},{"id":"5312006b-36ef-4aa9-b122-0dcf7e20be1a","keyword":"高碱度","originalKeyword":"高碱度"},{"id":"3b880b3a-f4dc-4d85-84d8-a4e9b7b2865d","keyword":"工艺参数","originalKeyword":"工艺参数"},{"id":"b2567d79-51ec-4af9-a0f1-738a9e92f164","keyword":"氧化亚铁配矿","originalKeyword":"氧化亚铁配矿"}],"language":"zh","publisherId":"gt200607002","title":"低硅细赤铁精矿生产高碱度烧结矿的研究及生产实践","volume":"41","year":"2006"},{"abstractinfo":"按球团矿在鞍钢2 580m3高炉内不同高度位置的温度条件、气氛及停留时间,在实验室动态模拟了炉料在高炉内的升温还原变化过程.通过球团升温还原膨胀试验、不同温度下恒温还原试验和900℃标准检测结果对比分析,得出了在高炉条件下的还原膨胀率低于检验标准的900℃膨胀率;鞍钢球团矿还原膨胀在正常范围内,但对弓一球团还原膨胀也应引起重视.鞍钢高炉使用酸性球团矿的配比在20%~30%时,熔滴性能相差不大.高炉使用球团矿比例由25%提高到30%后,炉况波动的主要原因不在于球团矿比例增加.通过生产一定镁或钙含量的球团均可降低球团矿还原膨胀及改善熔滴性能,从而可提高球团矿使用比例.","authors":[{"authorName":"于淑娟","id":"1ee0e550-9253-40fe-9cb7-ef225908dc2e","originalAuthorName":"于淑娟"},{"authorName":"刘万山","id":"3d1459af-1db8-47e8-af53-3074fdbbb40b","originalAuthorName":"刘万山"},{"authorName":"王向锋","id":"783a9656-4e79-42aa-8e92-201750b9718f","originalAuthorName":"王向锋"},{"authorName":"于素荣","id":"e3e1aed0-a251-408d-b292-2290bb8a3c01","originalAuthorName":"于素荣"},{"authorName":"侯洪宇","id":"95a6a9f7-f42f-404e-a224-5449f5699590","originalAuthorName":"侯洪宇"},{"authorName":"张立国","id":"9ac5cf72-0ee7-40cf-af01-db1b2433892a","originalAuthorName":"张立国"}],"doi":"","fpage":"7","id":"5e1aa0f6-7673-4a58-b9bb-b7f04c598922","issue":"8","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"708ed54d-05cd-435a-b1e8-cb8756cf0189","keyword":"球团矿","originalKeyword":"球团矿"},{"id":"2180c9a8-c222-4a75-8281-c4f7e47f8ede","keyword":"膨胀","originalKeyword":"膨胀"},{"id":"3c4b2299-09c2-41a8-9e02-3b9cb24d6455","keyword":"熔滴","originalKeyword":"熔滴"},{"id":"83e66502-024b-4b95-bc8d-67874d115969","keyword":"热模拟","originalKeyword":"热模拟"},{"id":"cad99c78-9ac3-4480-81d2-82ea18e7327b","keyword":"高炉","originalKeyword":"高炉"}],"language":"zh","publisherId":"gt201008002","title":"鞍钢炉料冶金性能动态热模拟试验研究","volume":"45","year":"2010"},{"abstractinfo":"以含铁尘泥中的碳作为还原剂,配制成具有自还原特性的尘泥球团。利用铁水倒罐后的鱼雷罐余热使尘泥球预热,在出铁后发生自还原反应,实现循环回收而不影响钢铁冶炼生产。这种方法可以很好地回收尘泥中的铁资源,目前在鞍钢已经得到了比较广泛的应用。近期少数鱼雷罐出现泡沫渣现象,影响了鱼雷罐正常铁水的倒罐速度。通过理论分析和实验验证,总结得出了泡沫渣形成的主要原因和控制方法。","authors":[{"authorName":"张大奎","id":"11d1c926-5de5-46be-a458-5984d09850d3","originalAuthorName":"张大奎"},{"authorName":"于淑娟","id":"0d9605d2-cc0d-45fb-b4a3-75ea594f40cb","originalAuthorName":"于淑娟"},{"authorName":"耿继双","id":"05df78a4-8f9a-49b7-aeef-db4b2494939a","originalAuthorName":"耿继双"},{"authorName":"侯洪宇","id":"8113f01d-a9f4-4719-8120-666270bfe387","originalAuthorName":"侯洪宇"},{"authorName":"王向锋","id":"446a1456-07a6-4cc3-99ed-560e71bceeca","originalAuthorName":"王向锋"}],"doi":"","fpage":"89","id":"6bfedf70-c0cc-4aa9-9d7e-7a27bd451350","issue":"11","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"1eb4c3b3-acc1-4cde-a1b7-b5544858f931","keyword":"尘泥球团","originalKeyword":"尘泥球团"},{"id":"ce227516-d3b9-4fcf-af56-d2805f1ec7f5","keyword":"循环利用","originalKeyword":"循环利用"},{"id":"09c4808c-69a5-41fa-bf00-726bf0fcd76c","keyword":"鱼雷罐","originalKeyword":"鱼雷罐"},{"id":"841afee0-875e-463c-978c-4479d7a925b2","keyword":"泡沫渣","originalKeyword":"泡沫渣"}],"language":"zh","publisherId":"gt201211018","title":"鱼雷罐中泡沫渣的成因与控制","volume":"47","year":"2012"},{"abstractinfo":"以含铁尘泥中的碳作为还原剂,配制成具有自还原特性的尘泥团块,利用钢厂现有生产工艺和设备使其中的铁氧化物及锌氧化物实现自还原回收而不影响钢铁冶炼生产。开发了利用转炉热环境、兑铁后铁水罐的余热和高炉铁水的物理热处理含铁尘泥工艺技术及其配套的含铁尘泥团块制造技术,实现了高炉后短流程循环处理含锌尘泥或高铁低杂质尘泥及烧结-高炉系统处理低锌低品质含铁尘泥多种途径的综合处理技术。在不引起高炉锌富集的前提下,实现了含铁尘泥的高效综合利用。","authors":[{"authorName":"于淑娟","id":"e66b0409-f642-4ba2-bd3c-f91e53ba722e","originalAuthorName":"于淑娟"},{"authorName":"侯洪宇","id":"dbc82cf3-b42b-4970-a55f-bf6cd06a4cca","originalAuthorName":"侯洪宇"},{"authorName":"王向锋","id":"c3c91a89-733c-42e9-82ca-997c33a0626e","originalAuthorName":"王向锋"},{"authorName":"耿继双","id":"4126b6f5-44f6-433e-b515-4f44c92b163f","originalAuthorName":"耿继双"},{"authorName":"张大奎","id":"d477a10a-e6e4-47d7-8404-bb3fdf3f7ffd","originalAuthorName":"张大奎"}],"doi":"","fpage":"68","id":"92ef0af7-d269-4918-8738-c964cb2106d4","issue":"7","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"8a2a0f13-e73b-426a-bb22-90b5c75ff11c","keyword":"尘泥","originalKeyword":"尘泥"},{"id":"91fbebda-fa0e-4d2c-90bc-1b58a6eab736","keyword":"自还原","originalKeyword":"自还原"},{"id":"639d6c6b-43ac-4b8a-b337-d4f3d3e3a6e0","keyword":"转炉","originalKeyword":"转炉"},{"id":"1a78971f-9a2d-4759-bf47-a7d573a09fee","keyword":"铁水罐","originalKeyword":"铁水罐"}],"language":"zh","publisherId":"gt201207015","title":"鞍钢含铁尘泥再资源化研究与实践","volume":"47","year":"2012"},{"abstractinfo":"目前,中国各大钢厂烧结机头除尘灰均存在不同程度的碱金属和重金属超标现象.很多企业将这部分固废直接返回烧结使用,致使有害元素循环富集,严重影响除尘效率、烧结矿质量以及高炉的顺行.提出了一种机头电除尘灰资源化方法,采用水浸、磁选、过滤、蒸发等工艺,去除其中的有害元素,并开发出二次提纯结晶的方法,将KCl质量分数由93.0%提高到99.8%,成倍地增加了其经济价值,为烧结机头除尘灰资源化处理提供了新的路线.","authors":[{"authorName":"钱峰","id":"2f952be7-1c2f-4372-9b65-1ca26bdee986","originalAuthorName":"钱峰"},{"authorName":"于淑娟","id":"811d42b3-8d40-40f3-979b-327664722c23","originalAuthorName":"于淑娟"},{"authorName":"侯洪宇","id":"ed1b5e8b-6097-466d-8389-e4b18bf8ea84","originalAuthorName":"侯洪宇"},{"authorName":"张大奎","id":"46cb28a3-c9a0-4d70-aca0-2f4be4308c36","originalAuthorName":"张大奎"},{"authorName":"耿继双","id":"a177414e-dd1d-4f70-8619-bbd43bd1ca3d","originalAuthorName":"耿继双"},{"authorName":"徐鹏飞","id":"03e09c4e-62e1-4035-8ff3-3d2fd6c01e0e","originalAuthorName":"徐鹏飞"}],"doi":"10.13228/j.boyuan.issn0449-749x.20150262","fpage":"67","id":"d03ad221-e688-46a1-b869-c0abd4bfce83","issue":"12","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"f0f6d45f-ea63-49b1-bf44-609b62f372b6","keyword":"烧结除尘灰","originalKeyword":"烧结除尘灰"},{"id":"8bfcb60b-035f-4d20-9436-b3b69bb74ed2","keyword":"资源化再利用","originalKeyword":"资源化再利用"},{"id":"a973ebe3-77a8-4ab7-838e-88a228a866f7","keyword":"提氯化钾","originalKeyword":"提氯化钾"}],"language":"zh","publisherId":"gt201512012","title":"烧结机头电除尘灰资源化再利用","volume":"50","year":"2015"},{"abstractinfo":"通过对当前高炉喷煤普遍存在的诸如基本无综合原煤场、制粉系统基本没有建立相关数据库和优化模型,以及高炉操作者在对喷煤量等的调整上尚存一定的盲目性等问题进行了详细分析,并提出了相应的解决办法.","authors":[{"authorName":"刘德军","id":"b2672bf7-ce03-4831-b0fe-cd173340b8b7","originalAuthorName":"刘德军"},{"authorName":"于淑娟","id":"3e2ceb5d-ac6a-4b73-b4a9-caf6bacd8b75","originalAuthorName":"于淑娟"},{"authorName":"王尤清","id":"c2900d22-bc02-4abb-aa64-2949d21c9c5b","originalAuthorName":"王尤清"},{"authorName":"王再义","id":"f08bfcc8-f3ec-46e1-874e-6cc1ce662ec1","originalAuthorName":"王再义"}],"doi":"10.3969/j.issn.1006-9356.2007.02.015","fpage":"56","id":"dc038cf3-8255-4623-af62-da2870091480","issue":"2","journal":{"abbrevTitle":"ZGYJ","coverImgSrc":"journal/img/cover/ZGYJ.jpg","id":"87","issnPpub":"1006-9356","publisherId":"ZGYJ","title":"中国冶金"},"keywords":[{"id":"b0be0be1-9f89-4519-ba90-3650c1dbe8fb","keyword":"高炉喷煤","originalKeyword":"高炉喷煤"},{"id":"b234c00b-106b-4ec1-a774-25df0027f354","keyword":"原煤综合料场","originalKeyword":"原煤综合料场"},{"id":"810ce86b-b883-471d-91cd-33bf46e29a9f","keyword":"数据库","originalKeyword":"数据库"},{"id":"dda7aa3b-0ad6-470c-a889-f959eff6c22d","keyword":"优化模型","originalKeyword":"优化模型"},{"id":"182f2d90-7884-4b5b-9437-2b10b3d74503","keyword":"置换比","originalKeyword":"置换比"},{"id":"50cea5be-5b5f-4971-9b7d-cbeb09615254","keyword":"最佳喷煤比","originalKeyword":"最佳喷煤比"}],"language":"zh","publisherId":"zgyj200702015","title":"当前高炉喷煤存在的问题及解决途径","volume":"17","year":"2007"},{"abstractinfo":"以含铁尘泥中的碳作为还原剂,配制成具有自还原特性的尘泥团块,利用钢厂现有生产工艺和设备使其中的铁氧化物及锌氧化物实现自还原回收而不影响钢铁冶炼生产。开发了利用转炉热环境、兑铁后铁水罐的余热和高炉铁水的物理热处理含铁尘泥工艺技术及其配套的含铁尘泥团块制造技术,实现了高炉后短流程循环处理含锌尘泥或高铁低杂质尘泥及烧结-高炉系统处理低锌低品质含铁尘泥多种途径的综合处理技术。在不引起高炉锌富集的前提下,实现了含铁尘泥的高效综合利用。","authors":[{"authorName":"于淑娟","id":"0b529187-9377-4083-abcc-99bf11f20545","originalAuthorName":"于淑娟"},{"authorName":"侯洪宇","id":"7f2d98fd-2d58-4e62-a02f-34dce6b74f40","originalAuthorName":"侯洪宇"},{"authorName":"王向锋","id":"baff9001-98d1-4bc6-ad2a-00eb18844784","originalAuthorName":"王向锋"},{"authorName":"耿继双","id":"c3e9dc20-3271-4c72-af89-5cde556bf722","originalAuthorName":"耿继双"},{"authorName":"张大奎","id":"784f9361-d245-428d-a7cd-0e83ae83f9d1","originalAuthorName":"张大奎"}],"categoryName":"|","doi":"","fpage":"68","id":"f944fa49-316e-4b2f-8e08-9bd4af8eb350","issue":"7","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"f00a3291-a2b0-4914-b4a6-9fb7f58d83e7","keyword":"尘泥 ","originalKeyword":"尘泥 "},{"id":"bd3db51a-844b-4c6a-aadb-cd433e65ee03","keyword":" self deoxidize ","originalKeyword":" self deoxidize "},{"id":"a25b3588-9d1e-4229-8e0a-409ab05ebc51","keyword":" converter ","originalKeyword":" converter "},{"id":"d4ba6216-0af3-48bd-a50a-276cca062d66","keyword":" molten iron pot","originalKeyword":" molten iron pot"}],"language":"zh","publisherId":"0449-749X_2012_7_8","title":"鞍钢含铁尘泥再资源化研究与实践","volume":"47","year":"2012"},{"abstractinfo":"通过溶液聚合合成了一种梳状复合型高分子光稳定剂P(HAPBT-co-MTMP-co-OA-co-mPEGA).采用红外光谱、核磁共振、热重分析对高分子光稳定剂进行了表征,结果表明,高分子光稳定剂的热分解温度明显高于中间体(2',4'-二羟基苯基)-2H-苯并三唑(DHPBZ)的分解温度.将该光稳定剂应用到PP/剑麻纤维(SF)与PE/SF复合材料中能提高其抗紫外老化性能.通过测试复合材料老化前后的拉伸性能、接触角、羰基指数、乙烯基指数、水萃取损失率、热迁移损失率、扫描电镜等研究了光稳定剂的稳定化效果,并与低分子紫外线吸收剂UV-P的应用性能进行对比.结果表明,老化50 d后,添加高分子光稳定剂的PP/SF和PE/SF复合材料拉伸强度保持率分别比其空白复合材料少下降了37.41%和38.17,而添加UVP的PP/SF和PE/SF复合材料的拉伸强度保持率分别比其空白复合材料少下降了12.72%和12.85%.添加高分子光稳定的PP/SF和PE/SF复合材料羰基指数分别增加了0.033和0.018,乙烯基指数分别增加了0.07和0.039,增加幅度均较小;接触角测试结果表明无论是否添加光稳定剂的PP/SF和PE/SF接触角均随老化程度的加深而降低,但添加光稳定剂的复合材料接触角降低幅度明显低于空白复合材料;扫描电镜显示光稳定剂的加入使材料老化后表面裸露出剑麻纤维的表面积相对较小,产生的裂纹也较少;高分子光稳定剂具有优于UV-P的耐热水萃取与耐热迁移性能.","authors":[{"authorName":"于淑娟","id":"6d60a79a-69a8-4bd5-b38e-ca2459f9c3a0","originalAuthorName":"于淑娟"},{"authorName":"韦德麟","id":"435a15d7-5a2b-4c08-947c-655a0cb1193b","originalAuthorName":"韦德麟"},{"authorName":"陆树文","id":"cfcd3e26-ed35-41c8-a0df-79447a9aebf2","originalAuthorName":"陆树文"},{"authorName":"莫羡忠","id":"482c449a-b10b-4fba-8ed6-7d859f0eb30d","originalAuthorName":"莫羡忠"},{"authorName":"杨芳","id":"a3d2481d-b24f-4b0c-9f79-85e46696a544","originalAuthorName":"杨芳"},{"authorName":"梁春群","id":"8b94106e-bb9d-45f3-9264-c053678ef17b","originalAuthorName":"梁春群"}],"doi":"10.16865/j.cnki.1000-7555.2016.08.005","fpage":"21","id":"8ad6c540-3a54-4cdd-9280-22de22d1dc98","issue":"8","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":"3c7a7df8-a498-4501-8aa2-cc6caf79c1b1","keyword":"光稳定剂","originalKeyword":"光稳定剂"},{"id":"4de8f34f-0c97-4348-804a-6ee9a277f1a7","keyword":"剑麻纤维基复合材料","originalKeyword":"剑麻纤维基复合材料"},{"id":"ff0bebd2-f5d9-4518-9514-d7ae954ae28a","keyword":"紫外光老化","originalKeyword":"紫外光老化"},{"id":"b789d4d3-5894-48f6-9a5b-3971902d9e73","keyword":"聚丙烯","originalKeyword":"聚丙烯"},{"id":"fa69827a-4f2c-4b55-93ae-f4d488a7e623","keyword":"聚乙烯","originalKeyword":"聚乙烯"}],"language":"zh","publisherId":"gfzclkxygc201608005","title":"苯并三唑类光稳定剂的合成及在剑麻纤维基复合材料中的应用","volume":"32","year":"2016"}],"totalpage":982,"totalrecord":9811}