{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"介绍了攀钢用铝锰铁脱氧合金化生产高级别冷轧薄板用钢的可行性和脱氧合金化生产低碳铝镇静钢的工艺路线.采用铝锰铁脱氧合金化后,低碳铝镇静钢的炼成率从现工艺的85%提高到99%以上,并且冷轧薄板的表面质量有了大幅度的提高.","authors":[{"authorName":"汤天宇","id":"70dc6171-0d62-4879-b57d-accf73a36658","originalAuthorName":"汤天宇"},{"authorName":"栾秋生","id":"ea604138-d2b9-42a2-86ba-3ef61e4adbea","originalAuthorName":"栾秋生"},{"authorName":"文永才","id":"3f5010e0-17ce-4d54-9019-613b25c40760","originalAuthorName":"文永才"},{"authorName":"王胜","id":"2f4abd76-c617-4204-95ec-6e2933b4dbd1","originalAuthorName":"王胜"},{"authorName":"张槐","id":"1c19dfcc-ee23-4fdd-abd4-3a6159fd1cab","originalAuthorName":"张槐"},{"authorName":"陈守俊","id":"ceb2e06d-d3a3-424f-b0bf-1c959cea50ba","originalAuthorName":"陈守俊"}],"doi":"10.3969/j.issn.1004-7638.2000.04.010","fpage":"44","id":"e9431a4c-5200-433d-a144-ff6e25bc4c46","issue":"4","journal":{"abbrevTitle":"GTFT","coverImgSrc":"journal/img/cover/gtft1.jpg","id":"28","issnPpub":"1004-7638","publisherId":"GTFT","title":"钢铁钒钛"},"keywords":[{"id":"d6516dd1-519a-446e-919d-2d2e62639197","keyword":"铝锰铁合金","originalKeyword":"铝锰铁合金"},{"id":"73e0b7c0-c819-4c22-9869-8fc3ced4045c","keyword":"低碳铝镇静钢","originalKeyword":"低碳铝镇静钢"},{"id":"21e7e9d4-05b1-4bf3-a841-d6d35f683f80","keyword":"脱氧合金化","originalKeyword":"脱氧合金化"}],"language":"zh","publisherId":"gtft200004010","title":"低碳铝镇静钢铝锰铁脱氧合金化试验","volume":"21","year":"2000"},{"abstractinfo":"采用扫描电镜和能谱仪分析了金属型铸造和水冷铋锰铁合金均匀化处理前后的显微组织.研究结果表明,铋锰铁合金的铸态组织由BiMn相、Mn(Fe)相和铋相组成.铋锰铁合金金属型铸造组织中的铋相呈断续分布,而水冷组织中的铋相呈现连续分布形态.铋锰铁合金在400℃进行不同时间的均匀化处理后,合金的相组成没有发生改变,仍由BiMn相、Mn(Fe)相和铋相组成;随着均匀化时间的增加,合金中的BiMn相数量增加;金属型铸造铋锰铁合金在400 ℃均匀化处理16 h后,合金组织中BiMn相的数量不再变化,水冷铋锰铁合金在均匀化处理4h后,合金组织中BiMn相的数量基本稳定.铋锰铁合金经过均匀化处理后,合金组织中的BiMn相由原来的断续分布或孤立形态转化为连续分布形态.当金属型铸造铋锰铁合金在300℃下进行均匀化处理时,合金中形成的BiMn化合物数量更多,均匀化时间超过8h后,合金组织中BiMn相的数量基本稳定.","authors":[{"authorName":"李智","id":"c1825264-7a7b-4c47-bb92-db5a8a46b01a","originalAuthorName":"李智"},{"authorName":"李节林","id":"d8f2701c-0bdd-4e12-abbc-33c1bdfb195b","originalAuthorName":"李节林"},{"authorName":"王建华","id":"c312744d-15f0-49e8-ac5d-000b499454f4","originalAuthorName":"王建华"}],"doi":"","fpage":"35","id":"221e6489-cee8-4ffb-8e70-825c6bf5c5e0","issue":"z1","journal":{"abbrevTitle":"CLRCLXB","coverImgSrc":"journal/img/cover/CLRCLXB.jpg","id":"15","issnPpub":"1009-6264","publisherId":"CLRCLXB","title":"材料热处理学报"},"keywords":[{"id":"7ccb010e-6704-49bf-8be3-4100fd521218","keyword":"铋锰铁合金","originalKeyword":"铋锰铁合金"},{"id":"ccc25246-2d77-4369-95d9-964205f17ffa","keyword":"铸态组织","originalKeyword":"铸态组织"},{"id":"a3f9eabe-99e2-421c-98f3-41ff0901042f","keyword":"均匀化处理","originalKeyword":"均匀化处理"},{"id":"bd6cad78-3d41-48b2-a5f6-ae547c7824af","keyword":"均匀化组织","originalKeyword":"均匀化组织"}],"language":"zh","publisherId":"jsrclxb2013z1008","title":"均匀化处理对铋锰铁合金显微组织的影响","volume":"34","year":"2013"},{"abstractinfo":"YW某铁合金公司排放的锰铁合金渣为水淬渣,其Al2O3含量仅1.9%,该公司将液态锰铁合金渣加Al2O3调质用于生产矿棉,排放的风冷渣其Al2O3含量提高至8.7%,两种渣的质量系数均为1.0.通过与矿渣的对比研究表明:水淬渣活性高,但易磨性差;风冷渣活性低,易磨性好.锰铁合金渣Al2O3含量低、质量系数与活性比矿渣低,但比Al2O3含量高的矿棉渣活性好.物理方法可以激发锰铁合金渣及矿棉渣的潜在活性,且粉磨时间愈长,活性愈高.","authors":[{"authorName":"周明凯","id":"f3332672-9539-45d3-a311-e1ba860eaa53","originalAuthorName":"周明凯"},{"authorName":"周万伦","id":"940084ad-7d55-4e9a-b5ad-9fe06cad1230","originalAuthorName":"周万伦"},{"authorName":"陈潇","id":"dc1e2559-79aa-4e88-9882-641adac75bd2","originalAuthorName":"陈潇"}],"doi":"","fpage":"4180","id":"8acd2e8f-7ead-4ed8-8260-ef3ceb656e27","issue":"12","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"9e7048a5-dc32-4a2f-9b95-921d32271d25","keyword":"锰铁合金渣","originalKeyword":"锰铁合金渣"},{"id":"3c576c6f-10ef-4522-a73a-84ea57798c20","keyword":"易磨性","originalKeyword":"易磨性"},{"id":"77e16e48-37b8-4188-afa2-a88a9168b37c","keyword":"活性","originalKeyword":"活性"},{"id":"68f1a762-7418-44fe-a497-49345d300767","keyword":"物理激发","originalKeyword":"物理激发"}],"language":"zh","publisherId":"gsytb201612047","title":"锰铁合金渣与矿棉渣的易磨性与活性评价","volume":"35","year":"2016"},{"abstractinfo":"通过BaO-卤化物渣系和锰铁合金之间磷的分配平衡实验,测定了实验渣系的磷酸盐容量.结果表明,脱磷剂中不同卤化物的加入对增大渣系脱磷能力的影响程度不同,按大小顺序为BaF2>BaCl2>CaF2>CaCl2,实验得到CaO替代BaO,MnO2替代BaF2时对渣系脱磷能力的影响关系.在此基础上,用BaO-BaF2系熔剂对锰铁合金进行氧化脱磷工艺性实验,实验发现,采用56 %BaO-24 %BaF2-10 %Fe2O3-10 %MnO2熔剂,熔剂添加量为10 g/100 g合金,温度1573 K,脱磷率达到62 %,温度升高到1673 K,脱磷率降低到30 %.","authors":[{"authorName":"郭上型","id":"ef203e3d-5bd7-4d1b-a489-01ab4e019a17","originalAuthorName":"郭上型"},{"authorName":"董元()","id":"741ecef7-4982-4d69-81e4-91689cb93605","originalAuthorName":"董元()"}],"doi":"","fpage":"26","id":"41d56253-4cec-4cc5-a9ed-4d94c17ffc18","issue":"1","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"ca749f01-5954-4344-aca7-076f7ae4169f","keyword":"锰铁合金","originalKeyword":"锰铁合金"},{"id":"795dc452-4f4c-4a2e-93e7-bd3dfba79d7e","keyword":"BaO-卤化物系熔剂","originalKeyword":"BaO-卤化物系熔剂"},{"id":"7a8be61e-874c-4044-929f-b86c282d6bae","keyword":"磷酸盐容量","originalKeyword":"磷酸盐容量"},{"id":"1ff45dd4-028f-425d-b57b-7b372615100b","keyword":"脱磷率","originalKeyword":"脱磷率"}],"language":"zh","publisherId":"gt199801006","title":"锰铁合金用BaO-卤化物渣系脱磷的实验","volume":"33","year":"1998"},{"abstractinfo":"高炉锰铁渣具有潜在水硬活性,可以用作胶凝材料,部分取代水泥.由于其水硬活性受多种因素的影响,文中采用均匀设计及回归分析的方法,研究了锰铁渣在水泥中的掺入量、水胶比、激发剂(生石灰和无水石膏)加入量4种因素对锰铁渣水硬活性的影响,最终发现各因素影响程度由大到小依次为:水胶比>锰铁渣掺入量>无水石膏掺入量>生石灰掺入量.运用Matlab分析探求了最佳水化条件及通过室内试验对优化结果进行了论证,同时对激发剂的激发机理进行分析,为生石灰及无水石膏的添加提供理论依据.","authors":[{"authorName":"李辉","id":"73d47387-ba0a-40de-98af-ac8932237f23","originalAuthorName":"李辉"},{"authorName":"王洪江","id":"6f0de9e0-6a02-4b1e-9cbd-ae1c051fa6f1","originalAuthorName":"王洪江"},{"authorName":"吴爱祥","id":"8b058dbd-e589-4497-9c7d-afd0c62c3f76","originalAuthorName":"吴爱祥"},{"authorName":"胡凯健","id":"b54289c7-cda2-437b-84a3-46a973e6b574","originalAuthorName":"胡凯健"},{"authorName":"熊有为","id":"a850ec29-0914-4f3e-a59a-8481bb2fb87c","originalAuthorName":"熊有为"}],"doi":"10.3969/j.issn.1001-1277.2012.04.007","fpage":"27","id":"5dbd85fb-0774-48b8-a8a1-07a5df6bd7dc","issue":"4","journal":{"abbrevTitle":"HJ","coverImgSrc":"journal/img/cover/HJ.jpg","id":"44","issnPpub":"1001-1277","publisherId":"HJ","title":"黄金"},"keywords":[{"id":"2c5c5342-8e6e-4f07-b017-061730f0a6c7","keyword":"锰铁渣","originalKeyword":"锰铁渣"},{"id":"a1b55c0e-2999-430b-b7b6-bf14a95efdbf","keyword":"水硬活性","originalKeyword":"水硬活性"},{"id":"c2fad9b4-85f1-42a4-8de2-ec8049c302cf","keyword":"均匀设计","originalKeyword":"均匀设计"},{"id":"ef6f2ca5-1aaf-48d5-9694-1202f1ccd49a","keyword":"回归分析","originalKeyword":"回归分析"},{"id":"f52a37d6-a8bc-416a-ac0b-213f8252ca37","keyword":"理论依据","originalKeyword":"理论依据"}],"language":"zh","publisherId":"huangj201204007","title":"高炉锰铁合金渣水硬活性影响因素研究","volume":"33","year":"2012"},{"abstractinfo":"以10 MV·A半敞开矿热炉为研究对象,通过对其过去生产高碳锰铁存在的问题进行研究分析,总结了炉衬砌筑方式改进、原燃料选择改进、电极压放和管控改进、下料管改为水冷、稳定送电负荷在140~145 A、电压级稳定使用5级等改进措施,使矿热炉工艺参数更适合生产高碳锰铁,减少了电极事故.并对所用矿石和焦炭进行重新选择,减少白云石的配入量,降低渣铁比,减少了渣量,使各项技术经济指标得到较大改善,平均日产量达到66.38 t,冶炼电耗降低至2 609 kW· h/t,取得了巨大的经济效益.","authors":[{"authorName":"黄文","id":"a690770e-0738-4df1-9585-2c3b4e2161e9","originalAuthorName":"黄文"}],"doi":"10.13228/j.boyuan.issn1006-9356.20160271","fpage":"74","id":"a7f4b20e-487a-4c8f-9416-17db69e3a823","issue":"3","journal":{"abbrevTitle":"ZGYJ","coverImgSrc":"journal/img/cover/ZGYJ.jpg","id":"87","issnPpub":"1006-9356","publisherId":"ZGYJ","title":"中国冶金"},"keywords":[{"id":"4de0ff1f-1c55-4a85-8c55-968a86221162","keyword":"10 MV·A矿热炉","originalKeyword":"10 MV·A矿热炉"},{"id":"2f18d5b5-dc82-4717-8b25-4e944ce364fa","keyword":"半敞开","originalKeyword":"半敞开"},{"id":"bdb52cb3-e8a3-45d8-b6b4-5f7fb9e82c7d","keyword":"高碳锰铁","originalKeyword":"高碳锰铁"},{"id":"81b0fac0-6cc0-4551-86fc-b33564bcbef8","keyword":"改进","originalKeyword":"改进"}],"language":"zh","publisherId":"zgyj201703016","title":"改进10MV·A矿热炉生产高碳锰铁合金实践","volume":"27","year":"2017"},{"abstractinfo":"介绍了硼酸镶边垫底粉末压片X荧光光谱法分析稀土铝铁合金中稀土、硅、铝、磷等元素的方法.","authors":[{"authorName":"张术杰","id":"e0ff082d-1c78-48dc-a442-f9a72960fd59","originalAuthorName":"张术杰"},{"authorName":"吴文琪","id":"48688da3-42db-4711-94f6-1e5ccd105ba5","originalAuthorName":"吴文琪"},{"authorName":"蒋天怡","id":"405edec9-b88e-4b0d-9a47-5c5c4374d477","originalAuthorName":"蒋天怡"},{"authorName":"赵长玉","id":"3e8b2f30-273b-464b-aa9c-c9b53c245cb0","originalAuthorName":"赵长玉"}],"doi":"10.3969/j.issn.1004-0277.2012.04.016","fpage":"77","id":"5f3252f5-0ea4-460d-af83-f27f5e77a50b","issue":"4","journal":{"abbrevTitle":"XT","coverImgSrc":"journal/img/cover/XT.jpg","id":"65","issnPpub":"1004-0277","publisherId":"XT","title":"稀土"},"keywords":[{"id":"794a6e2f-7613-4dcd-ac91-9b020b35dcd3","keyword":"X射线荧光光谱法(XRF)","originalKeyword":"X射线荧光光谱法(XRF)"},{"id":"114d29d3-1aae-443b-a8e4-29b35c2d1b49","keyword":"粉末压片法","originalKeyword":"粉末压片法"},{"id":"4100a5cf-835d-4a6e-8f80-7bb244d9a9c2","keyword":"稀土铝铁合金(RE-Al-Fe)","originalKeyword":"稀土铝铁合金(RE-Al-Fe)"}],"language":"zh","publisherId":"xitu201204016","title":"X荧光光谱法分析稀土铝铁合金中稀土、铝、硅、磷","volume":"33","year":"2012"},{"abstractinfo":"以铝粉和铁粉为原料,采用冷压烧结方法制备出铝-铁合金,并进行热挤压加工,研究了它的纽织和性能.结果表明:随着铁含量增加,抗拉强度先升后降,伸长率下降,硬度和耐磨性增高;Al、Al-10Fe和Al-20Fe合金的磨损体积损失分别是QSn6.5-0.4的1/0.66,1/12.2和1/20.1,磨损表面呈铝基体、Al13Fe4硬质相和少量孔隙的耐磨组织.","authors":[{"authorName":"王宏宇","id":"dfbfa3e3-cb08-46fe-a020-610243e6596f","originalAuthorName":"王宏宇"},{"authorName":"刘桂林","id":"fbb0308f-c640-4ac9-a071-881c4a346f92","originalAuthorName":"刘桂林"},{"authorName":"吉平平","id":"a4acdf83-15a3-4f79-aa71-07c000107a99","originalAuthorName":"吉平平"},{"authorName":"陈康敏","id":"42f14361-e409-4ccd-9fcf-540252e163ed","originalAuthorName":"陈康敏"},{"authorName":"许晓静","id":"a10ea42a-0547-48b5-bce7-deb7d6eb126a","originalAuthorName":"许晓静"}],"doi":"10.3969/j.issn.1000-3738.2005.09.015","fpage":"48","id":"2153acd9-5d6c-4ddc-ac2d-d4f20b4ea084","issue":"9","journal":{"abbrevTitle":"JXGCCL","coverImgSrc":"journal/img/cover/JXGCCL.jpg","id":"45","issnPpub":"1000-3738","publisherId":"JXGCCL","title":"机械工程材料"},"keywords":[{"id":"4d1a7d90-4971-4fe9-86fe-00b1aa854348","keyword":"铝-铁合金","originalKeyword":"铝-铁合金"},{"id":"dd5aa378-db85-4269-b1cb-6d1e1cd20ffd","keyword":"组织","originalKeyword":"组织"},{"id":"47d67feb-7c91-4483-b996-bc782e445be8","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"7ad2c52e-560f-48ec-bb35-1e5cf03962d6","keyword":"磨损行为","originalKeyword":"磨损行为"}],"language":"zh","publisherId":"jxgccl200509015","title":"粉末冶金铝-铁合金的组织和性能","volume":"29","year":"2005"},{"abstractinfo":"将钛铁样品经强氧化剂过氧化钠于高温熔融分解,使铁、钛等生成沉淀与磷、铝分离.分取部分滤液以酚酞为指示剂,用硝酸酸化,在0.8~1.2 mol/L硝酸介质中,加入钼酸铵溶液,使磷生成磷钼杂多酸,用正丁醇-三氯甲烷萃取,以氯化亚锡溶液将磷钼杂多酸还原为磷钼蓝,于波长680 nm处测量其吸光度.当分取的部分滤液用盐酸酸化时,加入过量乙二胺四乙酸二钠(EDTA),调节pH值为5.8~6.2,用锌标准溶液滴定过量的EDTA,可以以氟化物将铝置换,释放出与铝相当量的EDTA.再用锌标准溶液滴定所取代出的EDTA,据此计算铝的含量.本方法具有稳定性较高、简便、快速、准确的特点.","authors":[{"authorName":"寿秋枫","id":"3e06afe1-89ed-4b20-be9f-da6acddc6a96","originalAuthorName":"寿秋枫"}],"doi":"","fpage":"47","id":"a30b79f5-6d98-4341-a0c6-33538e64b932","issue":"2","journal":{"abbrevTitle":"JSGNCL","coverImgSrc":"journal/img/cover/JSGNCL.jpg","id":"46","issnPpub":"1005-8192","publisherId":"JSGNCL","title":"金属功能材料"},"keywords":[{"id":"ed018c57-e549-4971-aaf2-88d39daf8214","keyword":"钛铁","originalKeyword":"钛铁"},{"id":"c3fdd9b4-3099-4911-980f-616fc9c1c478","keyword":"磷","originalKeyword":"磷"},{"id":"8fb5873a-72d6-4832-951a-ca0fcda0cfb1","keyword":"铝","originalKeyword":"铝"},{"id":"f95c4448-42ed-44c3-a07b-629c1848d956","keyword":"连续测定","originalKeyword":"连续测定"},{"id":"68d7b583-dcf8-4d66-af36-2e87d151f504","keyword":"分光光度法","originalKeyword":"分光光度法"},{"id":"e9ba1a4a-81e5-49ae-9075-204188f8656b","keyword":"滴定法","originalKeyword":"滴定法"}],"language":"zh","publisherId":"jsgncl201102011","title":"钛铁合金中磷、铝的连续测定","volume":"18","year":"2011"},{"abstractinfo":"钒铁是生产工具钢、耐热钢的一种重要中间合金,目前主要采用铝热法生产.本文应用决策树分类方法来分析铝热还原生产铁合金的工艺和技术参数,主要考查了原料品位、发热量、配铝系数、反应时间、喷吹时间、喷吹量等主要工艺参数对产品回收率、铝含量含量的影响,给出各工艺参数对它们的影响模式.由于处理的数据是实际生产数据,数据分析结果可直接用于指导改进生产工艺.","authors":[{"authorName":"宋宝平","id":"f71aa927-b680-4a28-be46-ffb23da6e5b4","originalAuthorName":"宋宝平"},{"authorName":"薛济来","id":"70c76220-fbed-42bc-9472-57ada9975ab0","originalAuthorName":"薛济来"},{"authorName":"铁军","id":"ff77b274-4d80-44c0-9164-c6426175b07c","originalAuthorName":"铁军"},{"authorName":"李幼军","id":"c83ac0e7-1359-47b1-aff9-6577eb3ac508","originalAuthorName":"李幼军"},{"authorName":"王若宾","id":"70b4fa3e-9ebc-4f38-a2c8-e290b0bcdfe4","originalAuthorName":"王若宾"}],"doi":"10.3969/j.issn.0258-7076.2006.z2.028","fpage":"114","id":"0e1f27c1-f756-4f10-8712-40b615250932","issue":"z2","journal":{"abbrevTitle":"XYJS","coverImgSrc":"journal/img/cover/XYJS.jpg","id":"67","issnPpub":"0258-7076","publisherId":"XYJS","title":"稀有金属"},"keywords":[{"id":"d504082f-a133-4ca3-ae4d-e6fa6ea6bfc4","keyword":"铝热还原","originalKeyword":"铝热还原"},{"id":"33b16556-5025-4d05-8c6f-a72d84f411f2","keyword":"钒铁","originalKeyword":"钒铁"},{"id":"37fe7d7a-70c6-4fa8-98a1-35bdd851f1e1","keyword":"决策树分析","originalKeyword":"决策树分析"},{"id":"51543ba2-e56f-4985-bd72-9f3a2994d1d9","keyword":"工艺优化","originalKeyword":"工艺优化"}],"language":"zh","publisherId":"xyjs2006z2028","title":"铝热还原生产钒铁合金的工艺优化","volume":"30","year":"2006"}],"totalpage":4520,"totalrecord":45199}