{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"通过对LZ50车轴钢边部增碳缺陷进行金相检验和扫描电镜检验,发现增碳处组织异常,全部为珠光体,伴随大量MnS和硅酸盐夹杂物.现场排查发现在保温帽和铸模之间有较大的缝隙,缝隙中残留有大量粉渣,而且使用的保护渣为高碳型保护渣.由此判断,浇铸过程中钢水与缝隙中的粉渣接触造成钢锭帽口线增碳,而且钢水中未被保护渣完全吸收的夹杂物也被捕捉残留在钢坯表面.","authors":[{"authorName":"李吉东","id":"4239215a-85c3-4e36-bb36-565729a660b2","originalAuthorName":"李吉东"},{"authorName":"韩培德","id":"1d036260-1b8a-4477-90dc-9b40f9717ac4","originalAuthorName":"韩培德"},{"authorName":"王烽","id":"da74bd24-ac22-4138-b4ff-a3b3da4f03be","originalAuthorName":"王烽"},{"authorName":"任永秀","id":"87dbbd78-7ec4-454d-a3d1-f1820fd4209c","originalAuthorName":"任永秀"},{"authorName":"贾元伟","id":"0bf9cdb6-7cba-4d49-8132-91730d793616","originalAuthorName":"贾元伟"},{"authorName":"李建春","id":"a29c0108-bf2a-49a1-918b-7777f6ea8488","originalAuthorName":"李建春"}],"doi":"10.13228/j.boyuan.issn1006-9356.20160162","fpage":"53","id":"06c0d4fb-bbb0-4460-881a-78acf75b829c","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":"1e8f5a9c-c21e-43aa-ab38-e28f9535efc3","keyword":"边部增碳","originalKeyword":"边部增碳"},{"id":"f661c8cb-139a-49f8-bbac-27651198008f","keyword":"夹杂物","originalKeyword":"夹杂物"},{"id":"06052595-8c4e-4995-ae64-48b05fffeda3","keyword":"帽口","originalKeyword":"帽口"},{"id":"c59a522a-fec4-43d4-9fc7-4646bc1264ad","keyword":"保护渣","originalKeyword":"保护渣"}],"language":"zh","publisherId":"zgyj201702013","title":"LZ50车轴钢边部增碳低倍缺陷的检验和分析","volume":"27","year":"2017"},{"abstractinfo":"对影响带钢表面质量的几种常见边部缺陷及形成机理进行了研究,采用关键过程数据分析和电镜观察相结合的方法明确了形态相似、诱因各异的形成特点.结果发现,外生夹杂导致的热轧带钢边部层状、线状缺陷区分布富含F、Na、Mg、Si等元素的块体,局部存在夹杂物与氧化铁的异质混合层.薄规格冷轧带钢叠轧类层状缺陷与轧制工艺参数设置有关,其层间组织光滑;边部线状缺陷异物刮痕特征明显,缺陷处无异物质点.研究结果为带钢表面缺陷的成因及判定提供了新的分析思路.","authors":[{"authorName":"王恩睿","id":"c28585b6-4865-46c1-af75-bfcd4c83c3be","originalAuthorName":"王恩睿"},{"authorName":"吝章国","id":"975c8f88-7839-4bba-b713-a82d0882e2f6","originalAuthorName":"吝章国"},{"authorName":"谷凤龙","id":"d07af519-5eb6-4a29-944e-a103998d8c5c","originalAuthorName":"谷凤龙"},{"authorName":"贾耿伟","id":"81601300-21f7-4bfc-9652-d4042981d7e3","originalAuthorName":"贾耿伟"},{"authorName":"王连轩","id":"e1e877d9-3fa9-4d3e-8a0e-0962f7ac32f6","originalAuthorName":"王连轩"},{"authorName":"程迪","id":"e7b36337-db39-488f-ae7f-de03ba562b73","originalAuthorName":"程迪"}],"doi":"10.7513/j.issn.1004-7638.2015.01.022","fpage":"114","id":"7a37cae6-7b0b-4709-bdcc-1ee4131e7011","issue":"1","journal":{"abbrevTitle":"GTFT","coverImgSrc":"journal/img/cover/gtft1.jpg","id":"28","issnPpub":"1004-7638","publisherId":"GTFT","title":"钢铁钒钛"},"keywords":[{"id":"b4669920-9453-40d8-b336-9b839fe93c12","keyword":"带钢","originalKeyword":"带钢"},{"id":"b919e5f6-6747-4047-abca-ae26c2ecef95","keyword":"表面质量","originalKeyword":"表面质量"},{"id":"637f4550-5f5f-4b04-a4d4-41459720cd74","keyword":"层状缺陷","originalKeyword":"层状缺陷"},{"id":"f9bd8bbf-e4a3-442b-9519-e94b57aa1bad","keyword":"线状缺陷","originalKeyword":"线状缺陷"}],"language":"zh","publisherId":"gtft201501022","title":"带钢边部表面缺陷原因分析","volume":"36","year":"2015"},{"abstractinfo":"在线测量板坯宽度很重要,LIMAB公司开发了板坯宽度测量技术.测量板坯宽度不仅对连铸重要,而且对轧钢工序也重要.测量装置可以安装在切割装置之前或之后,测量数据可以传输给其它系统或传输给网络系统.测量系统可以用于钢厂环境,测量元件用不锈钢保护,并用压缩空气冷却.测量的参数为板坯位置、边部轮廓、板坯宽度和板坯边部厚度.借助于准确的速度和温度数据,板坯长度也可以测量.这一系统可以测量的板坯最大厚度为700mm,离传感器的最大距离为2000mm,每次扫描时间为250微秒,可以产生500个测量数据.","authors":[{"authorName":"","id":"27a7eb71-f5a4-444d-a6e4-3fa38518c9de","originalAuthorName":""}],"doi":"","fpage":"260","id":"3e41ab22-9687-48d6-acf5-7dea82c738b7","issue":"z1","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"515bd298-d956-4a82-9fd6-0722a4a192ce","keyword":"激光测量","originalKeyword":"激光测量"},{"id":"b6c6d014-f269-4239-801a-238f26ec87d7","keyword":"宽度测量","originalKeyword":"宽度测量"},{"id":"ef13c28e-0f1d-48c9-9d10-8ba6af3c5818","keyword":"尺寸测量","originalKeyword":"尺寸测量"}],"language":"zh","publisherId":"gt2004z1060","title":"在线测量板坯边部形状","volume":"39","year":"2004"},{"abstractinfo":"对钢中碳含量、Ca/Als、拉速、结晶器振动及二冷制度等工艺因素进行了综合分析,并从理论上对钢中氮含量、钢中铝含量及AlN质点析出等方面进行了阐述,指出了影响CSP板卷边部裂纹的主要因素是结晶器振动和二冷制度,为生产实践中减少CSP板卷边部裂纹发生指明了方向。","authors":[{"authorName":"孙彦辉","id":"810751ac-b0ed-45a4-98ce-72db64bfa8e0","originalAuthorName":"孙彦辉"},{"authorName":"赵长亮","id":"4573185d-8db0-4301-9383-f4a20b2b0664","originalAuthorName":"赵长亮"},{"authorName":"蔡开科","id":"8610f67d-6adc-42c0-902d-81d5521fd813","originalAuthorName":"蔡开科"},{"authorName":"成小军","id":"64cf3090-d2dc-4ec5-a7cd-0654f503b972","originalAuthorName":"成小军"},{"authorName":"周春泉","id":"3d28fd0d-589b-430d-96aa-b5198dd52aa8","originalAuthorName":"周春泉"},{"authorName":"吴光亮","id":"e387a28d-a528-41cb-9247-615f13f36a79","originalAuthorName":"吴光亮"}],"categoryName":"|","doi":"","fpage":"39","id":"401a6a1e-945e-4d93-b34c-706f72403b0a","issue":"4","journal":{"abbrevTitle":"GTYJXB","coverImgSrc":"journal/img/cover/GTYJXB.jpg","id":"30","issnPpub":"1001-0963","publisherId":"GTYJXB","title":"钢铁研究学报"},"keywords":[{"id":"0317061d-988d-4626-8445-e53ddc2077b7","keyword":"CSP板卷;边部裂纹;结晶器振动;二次冷却","originalKeyword":"CSP板卷;边部裂纹;结晶器振动;二次冷却"}],"language":"zh","publisherId":"1001-0963_2007_4_13","title":"CSP板卷边部裂纹影响因素分析","volume":"19","year":"2007"},{"abstractinfo":"对钢中碳含量、Ca/Als、拉速、结晶器振动及二冷制度等工艺因素进行了综合分析,并从理论上对钢中氮含量、钢中铝含量及AlN质点析出等方面进行了阐述,指出了影响CSP板卷边部裂纹的主要因素是结晶器振动和二冷制度,为生产实践中减少CSP板卷边部裂纹发生指明了方向.","authors":[{"authorName":"孙彦辉","id":"b3006ca6-d42e-4ba5-b7a9-b1204b804b57","originalAuthorName":"孙彦辉"},{"authorName":"赵长亮","id":"87608656-70ef-41b2-933f-d3177aacafe6","originalAuthorName":"赵长亮"},{"authorName":"蔡开科","id":"f4885755-a321-4f72-bb56-75a5924e786c","originalAuthorName":"蔡开科"},{"authorName":"成小军","id":"14b41cd0-d670-472f-9332-326a0f338091","originalAuthorName":"成小军"},{"authorName":"周春泉","id":"473c83ab-fb30-46df-9d7a-5e06c57598b1","originalAuthorName":"周春泉"},{"authorName":"吴光亮","id":"aee897cc-9474-4a2a-abea-17cd17df8e66","originalAuthorName":"吴光亮"}],"doi":"","fpage":"39","id":"b63d1747-df17-4f74-9143-f57570b2f05a","issue":"4","journal":{"abbrevTitle":"GTYJXB","coverImgSrc":"journal/img/cover/GTYJXB.jpg","id":"30","issnPpub":"1001-0963","publisherId":"GTYJXB","title":"钢铁研究学报"},"keywords":[{"id":"5d5d43d9-16f6-405e-8e37-2758bc99b189","keyword":"CSP板卷","originalKeyword":"CSP板卷"},{"id":"5f79bc43-340e-41a2-b346-ee1bc3108af0","keyword":"边部裂纹","originalKeyword":"边部裂纹"},{"id":"873fbe42-c83c-42cc-b19e-3af7eb09dd59","keyword":"结晶器振动","originalKeyword":"结晶器振动"},{"id":"192f4e82-04af-499c-b10c-1afd6aa09a9a","keyword":"二次冷却","originalKeyword":"二次冷却"}],"language":"zh","publisherId":"gtyjxb200704009","title":"CSP板卷边部裂纹影响因素分析","volume":"19","year":"2007"},{"abstractinfo":"重点分析镀锡产品边部线状缺陷的生长机制和缺陷遗传规律.在大量现场试样分析的基础上,探讨轧制过程工艺对细线缺陷产生的影响.采用SEM,EDS等方式分析缺陷的形貌,成分及组织.结果表明,边部线状缺陷主要由炼钢的夹杂物、热轧带钢边部翘皮、氧化铁皮以及冷轧热轧工序边部擦划伤缺陷遗传所致.通过热轧辊形优化可以有效控制边部翘皮缺陷;通过系列工艺控制,可以有效避免夹杂物、擦划伤及氧化铁皮缺陷.镀锡产品边部线状缺陷率降低70%以上,产品质量得到有效改善.","authors":[{"authorName":"周旬","id":"14e8d83a-151d-4c00-97bd-bed9a65aeee9","originalAuthorName":"周旬"},{"authorName":"艾矫健","id":"c67a617d-5c4a-4618-b99b-6e792d7e163c","originalAuthorName":"艾矫健"},{"authorName":"王晓东","id":"0f9a110a-c25b-4d7d-abb2-a8f87704cc2a","originalAuthorName":"王晓东"},{"authorName":"徐海卫","id":"baef3f16-9ebb-4f8c-9e46-40af5ac4d5d5","originalAuthorName":"徐海卫"},{"authorName":"李瑞","id":"0becb234-d20c-4f3b-ad17-fecdddd1b938","originalAuthorName":"李瑞"},{"authorName":"夏银锋","id":"fed5a49f-2356-4941-b40f-b3fc4407d216","originalAuthorName":"夏银锋"},{"authorName":"王建功","id":"17e866bf-3a7d-44b8-b0af-9ca026f29c5a","originalAuthorName":"王建功"},{"authorName":"杨孝鹤","id":"ff484473-362c-4df2-a0e9-a791a6f612c5","originalAuthorName":"杨孝鹤"},{"authorName":"孙超凡","id":"102f4c01-7de1-4c49-b8a5-ccafa11a58c3","originalAuthorName":"孙超凡"}],"doi":"10.7513/j.issn.1004-7638.2016.05.028","fpage":"162","id":"1b81dd78-454d-472b-93f0-50e1efd84a56","issue":"5","journal":{"abbrevTitle":"GTFT","coverImgSrc":"journal/img/cover/gtft1.jpg","id":"28","issnPpub":"1004-7638","publisherId":"GTFT","title":"钢铁钒钛"},"keywords":[{"id":"2e163004-e11d-4eab-81b6-106e7a6a6ec4","keyword":"镀锡板","originalKeyword":"镀锡板"},{"id":"fd30d6e9-791f-416a-bf08-da02b40ca836","keyword":"线状缺陷","originalKeyword":"线状缺陷"},{"id":"083a48c3-9dc8-4b4b-99c8-d63b9a2d7214","keyword":"边部翘皮","originalKeyword":"边部翘皮"},{"id":"489159f9-09e1-4dc6-b292-47e076c63c20","keyword":"氧化铁皮","originalKeyword":"氧化铁皮"},{"id":"54fe050e-6cbe-4de4-8bb6-1d1bc1a85022","keyword":"擦划伤","originalKeyword":"擦划伤"},{"id":"ca08be22-6d6a-40ef-844d-f94a451bbfd2","keyword":"辊形优化","originalKeyword":"辊形优化"}],"language":"zh","publisherId":"gtft201605028","title":"镀锡产品边部线状缺陷分析与改进","volume":"37","year":"2016"},{"abstractinfo":"为了消除酸洗后显现在SPHC热轧带钢边部处的黑线缺陷,利用金相显微镜、扫描电镜、能谱仪等相关试验手段,研究分析了带钢边部黑线产生的原因.结果表明:带钢边部黑线缺陷处成分主要为Fe元素,组织为铁素体和少量珠光体,存在粗晶、混晶现象.黑线产生的主要原因是带钢边部存在裂纹,轧制过程中由于拉应力使边角部金属翻平到带钢表面形成黑线.通过改善带钢边角部质量和优化立辊辊型及轧制工艺,可有效消除黑线缺陷,保证良好产品质量,提高成材率,从而满足市场的需求.","authors":[{"authorName":"陈连生","id":"5f31977f-b696-4cbc-b70d-a65f13b3019f","originalAuthorName":"陈连生"},{"authorName":"谷辉格","id":"f547442e-9cc3-4098-9b7a-30b1a6724b7b","originalAuthorName":"谷辉格"},{"authorName":"宋进英","id":"bbbd11cf-4163-4f8f-b046-6452ae88c837","originalAuthorName":"宋进英"},{"authorName":"田亚强","id":"1ec5b548-034a-4f56-bfdd-b257fbbd4b7c","originalAuthorName":"田亚强"},{"authorName":"张大伟","id":"17c3eac8-3558-41c4-a99f-96d3549fd09f","originalAuthorName":"张大伟"},{"authorName":"魏英立","id":"9c09ea7d-d593-412b-ae2b-a6c0b3fb5338","originalAuthorName":"魏英立"},{"authorName":"沈永革","id":"96925be5-611c-4d00-9abd-775c48c5e2e1","originalAuthorName":"沈永革"}],"doi":"10.7513/j.issn.1004-7638.2013.02.020","fpage":"103","id":"01486997-d304-4bfb-9fac-83ca29eed1f4","issue":"2","journal":{"abbrevTitle":"GTFT","coverImgSrc":"journal/img/cover/gtft1.jpg","id":"28","issnPpub":"1004-7638","publisherId":"GTFT","title":"钢铁钒钛"},"keywords":[{"id":"a334601c-d1e3-4d35-8a50-bd1c4d71717c","keyword":"热轧带钢","originalKeyword":"热轧带钢"},{"id":"8c5eac60-df7c-4813-ace8-c30349dc60b0","keyword":"黑线","originalKeyword":"黑线"},{"id":"1b729c87-839d-43c0-b84f-d014d74464c2","keyword":"混晶","originalKeyword":"混晶"},{"id":"f7908568-98ce-4c29-b273-4b585380cf62","keyword":"微裂纹","originalKeyword":"微裂纹"},{"id":"704a28e9-d7e8-40a1-96a1-f106b2f58ae6","keyword":"翻平","originalKeyword":"翻平"},{"id":"8e075280-83eb-45bb-bfc7-aeb8bcb1339f","keyword":"立辊","originalKeyword":"立辊"}],"language":"zh","publisherId":"gtft201302020","title":"SPHC热轧带钢边部“黑线”研究","volume":"34","year":"2013"},{"abstractinfo":"边部减薄是带钢重要的断面质量指标,直接影响到边部切损的大小,与成材率有密切的关系.以六辊冷轧机为对象,采用影响函数法建立轧辊的弹性变形解析模型,分析了带钢入口厚度、压下率、变形抗力、前后张力、工作辊与中间辊的正负弯辊以及工作辊横移等因素对边部减薄的影响规律.研究结果表明,带钢入口厚度、压下率和变形抗力的变化对出口带钢横向厚度分布的影响结果相似,即随其数值的增大,中心板凸度Cc和边降Ce都随之增大.正弯辊力会减小Cc和Ce,工作辊横移会大大改善边部减薄,具体的横移量要根据不同品种、不同宽度以及不同轧制工艺来确定,而不能仅仅通过工作辊长度以及带材宽度来设计工作辊横移位置.","authors":[{"authorName":"常安","id":"737dd72b-9de5-412d-9d11-b469b89dc33a","originalAuthorName":"常安"},{"authorName":"邸洪双","id":"4db816e5-f9a6-43a4-9b46-7301cd3b1e4a","originalAuthorName":"邸洪双"},{"authorName":"白金兰","id":"2b338188-f234-4a87-9aa9-aaedd6b5315e","originalAuthorName":"白金兰"},{"authorName":"佟强","id":"83bbc276-2a53-48b7-8898-c4626e0eea4c","originalAuthorName":"佟强"},{"authorName":"阳代军","id":"e92dafe5-6cd7-4768-a4f3-0757e19cf586","originalAuthorName":"阳代军"}],"doi":"","fpage":"51","id":"25954cda-768c-449e-91ab-04ffededbdef","issue":"10","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"b513a803-1693-40b8-81cf-978164d3f0ce","keyword":"边部减薄","originalKeyword":"边部减薄"},{"id":"62aa9795-bd6a-4f88-bbec-d8dc9ed08fb5","keyword":"冷轧机","originalKeyword":"冷轧机"},{"id":"cd0f59e3-6344-481f-a4fc-04ece2ba10c0","keyword":"影响函数法","originalKeyword":"影响函数法"},{"id":"f03278f0-9479-48d9-811a-fd9cb07bf3ee","keyword":"工作辊横移","originalKeyword":"工作辊横移"},{"id":"579b5244-4b9a-41a1-8cc1-97af04225437","keyword":"轧辊弹性变形","originalKeyword":"轧辊弹性变形"}],"language":"zh","publisherId":"gt200710013","title":"影响冷轧边部减薄的因素","volume":"42","year":"2007"},{"abstractinfo":"对CSP工艺生产的热轧薄板边裂原因进行了金相检测、SEM和能谱等方法分析,结果表明:边部裂纹上表面和横截面裂纹附近组织与试样其他部位相同,均为铁素体+少量渗碳体,无脱碳组织,裂纹处主要元素为O、Si、Ca,且分布细长,有压碎痕迹,推测其为压碎的CaSiO3夹杂,并发现裂纹处有保护渣成分,推测SPHC边部裂纹是在轧制过程中形成的,且是由卷渣带入的大颗粒的CaSiO3夹杂,在轧制过程中,应力集中导致板卷开裂。","authors":[{"authorName":"彭其春,童志博,胡建文,杨柳,刘炳宇,钱龙","id":"fce8f823-60d8-4a33-92c2-c988983e4d3b","originalAuthorName":"彭其春,童志博,胡建文,杨柳,刘炳宇,钱龙"}],"categoryName":"|","doi":"","fpage":"36","id":"7721dbc9-0a68-4694-a068-cecf72340b8e","issue":"4","journal":{"abbrevTitle":"WLCS","coverImgSrc":"journal/img/cover/WLCS.jpg","id":"64","issnPpub":"1001-0777","publisherId":"WLCS","title":"物理测试"},"keywords":[{"id":"1c64c6bd-24de-4796-a75e-ec412718d593","keyword":"热轧薄板 ","originalKeyword":"热轧薄板 "},{"id":"43876c3a-7145-4dae-a398-7fe8edb65a42","keyword":" edge crack ","originalKeyword":" edge crack "},{"id":"a0236b8d-e723-4d69-9dcf-002ea2f93cb8","keyword":" CaSiO3 inclusion ","originalKeyword":" CaSiO3 inclusion "},{"id":"e0c628fb-e342-4765-a621-f507c5fc21cf","keyword":" slag entrainment","originalKeyword":" slag entrainment"}],"language":"zh","publisherId":"1001-0777_2012_4_4","title":"CSP热轧板卷边部裂纹成因初探","volume":"30","year":"2012"},{"abstractinfo":"对CSP工艺生产的热轧薄板边裂原因进行了金相检测、SEM和能谱等方法分析,结果表明:边部裂纹上表面和横截面裂纹附近组织与试样其他部位相同,均为铁素体+少量渗碳体,无脱碳组织,裂纹处主要元素为O、Si、Ca,且分布细长,有压碎痕迹,推测其为压碎的CaSiO3夹杂,并发现裂纹处有保护渣成分,推测SPHC边部裂纹是在轧制过程中形成的,且是由卷渣带入的大颗粒的CaSiO3夹杂,在轧制过程中,应力集中导致板卷开裂。","authors":[{"authorName":"彭其春","id":"621d205c-6e8e-4a25-afcb-6bf59ef55f0e","originalAuthorName":"彭其春"},{"authorName":"童志博","id":"56ed2659-eed1-4a8e-9251-a912118b5e3f","originalAuthorName":"童志博"},{"authorName":"胡建文","id":"72de0f3b-ac05-43f4-b7d2-d1058be00520","originalAuthorName":"胡建文"},{"authorName":"杨柳","id":"b30ea8f0-f172-4f37-8db1-56cc2a7c86a0","originalAuthorName":"杨柳"},{"authorName":"刘炳宇","id":"38bd89c0-be20-420b-aabc-d41f49f883cb","originalAuthorName":"刘炳宇"},{"authorName":"钱龙","id":"36ac4126-58d3-4c6b-987f-247c0cc509cf","originalAuthorName":"钱龙"}],"doi":"","fpage":"36","id":"a0e56e8b-2a82-4dc0-8b56-ad6fdad98368","issue":"4","journal":{"abbrevTitle":"WLCS","coverImgSrc":"journal/img/cover/WLCS.jpg","id":"64","issnPpub":"1001-0777","publisherId":"WLCS","title":"物理测试"},"keywords":[{"id":"3114e85c-b725-43f2-8ab7-036b4d6fc274","keyword":"热轧薄板","originalKeyword":"热轧薄板"},{"id":"da3006d0-e388-4f2d-bee8-d69f22e6f837","keyword":"边部裂纹","originalKeyword":"边部裂纹"},{"id":"5e747611-2dc3-4bc1-982d-f0cb9a4cf362","keyword":"CaSiO3夹杂","originalKeyword":"CaSiO3夹杂"},{"id":"0c70e412-c63b-4fb3-a087-46416ad26a36","keyword":"卷渣","originalKeyword":"卷渣"}],"language":"zh","publisherId":"wlcs201204011","title":"CSP热轧板卷边部裂纹成因初探","volume":"30","year":"2012"}],"totalpage":1601,"totalrecord":16003}