{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"采用多种材质料钵的不同粉碎机进行不同粒度或不同粉碎时间制备试样,检测试样中钒、料钵材质的特征元素和氧成分含量并分别计算它们的变化量,找到了料钵材质磨粉、空气中氧共同对试样的不同程度污染是导致钒含量偏低的原因.根据破碎机性能,选配制样设备并确定样品破碎粒度控制点,经试验确定制样方法的样品缩分K值为0.02.采取选用粉碎能力强且料钵材质耐磨性能较好的振动粉碎机粉碎样品、严格控制试样粒度、限时粉碎等措施,以减少污染.实验方法是先将原样用颚式破碎机破碎至粒度-10 mm,混匀后缩分留不少于2.0 kg样品,再颚式破碎至-5 mm,混匀后缩分留不少于0.5 kg样品;然后限时振动粉碎至-1.0 mm,混匀后缩分留不少于50 g样品;最后限时振动粉碎至分析试样粒度-0.250mm.实验方法对不易破碎的FeV50、FeV80的制样精确度(钒含量)βD分别为0.23、0.31,试样测定精确度βM分别为0.18、0.19,对6 kg大样制备成试样的时间为14 min.","authors":[{"authorName":"陈荣庆","id":"9fc6e4f8-7b16-4e58-bd14-6f8dbb71708d","originalAuthorName":"陈荣庆"},{"authorName":"张永刚","id":"6470fd0e-829c-47aa-9e11-48aae0830613","originalAuthorName":"张永刚"},{"authorName":"羊绍松","id":"faedde74-d056-49ba-bdd9-20b1d0091e27","originalAuthorName":"羊绍松"},{"authorName":"罗萍","id":"5a9c7a82-7831-4c17-aaf1-35b38daf1c69","originalAuthorName":"罗萍"}],"doi":"10.13228/j.boyuan.issn1000-7571.009801","fpage":"40","id":"19957e2a-ffc2-4498-b050-41fa0815418a","issue":"6","journal":{"abbrevTitle":"YJFX","coverImgSrc":"journal/img/cover/YJFX.jpg","id":"71","issnPpub":"1000-7571","publisherId":"YJFX","title":"冶金分析 "},"keywords":[{"id":"f307386d-c977-493b-983f-64ca348b12f4","keyword":"不易破碎钒铁","originalKeyword":"不易破碎钒铁"},{"id":"7c83e763-d208-4789-8aa0-b410c5b77e45","keyword":"破碎机性能","originalKeyword":"破碎机性能"},{"id":"54fbb5e6-b199-4d68-bd51-e6f1161b3137","keyword":"料钵材质磨粉","originalKeyword":"料钵材质磨粉"},{"id":"11ac8d13-b9ae-4c6e-875a-5502bbed2ab9","keyword":"氧","originalKeyword":"氧"},{"id":"86f1eb4d-3dc6-44c1-bde5-5761a10edc23","keyword":"污染试样","originalKeyword":"污染试样"},{"id":"32d35e02-1979-491f-a36c-04b4d5585c74","keyword":"制样方法","originalKeyword":"制样方法"}],"language":"zh","publisherId":"yjfx201606008","title":"不易破碎钒铁制样方法探讨","volume":"36","year":"2016"},{"abstractinfo":"通过弹用燃烧合金颗粒制备实验,研究燃烧合金颗粒的形貌、制备难易程度、利用率与海绵锆中铁含量的关系.结果表明:铁含量直接影响燃烧合金颗粒的形貌、制备难易程度和利用率,在其他成分符合标准的前提下,铁含量越高,燃烧合金越不易破碎成所需的颗粒;铁含量较低时,燃烧合金容易破碎且颗粒形貌呈海绵状,制备的燃烧合金产品表面光洁、强度高.","authors":[{"authorName":"吕建军","id":"4e979a55-5e8e-4d29-8119-cb23e2355498","originalAuthorName":"吕建军"},{"authorName":"高平","id":"2e40729c-2202-4181-980f-e2d2f0adb969","originalAuthorName":"高平"},{"authorName":"王力杰","id":"427b2fec-96e5-4e45-a904-8c5e7dd5e5ef","originalAuthorName":"王力杰"},{"authorName":"李永峰","id":"00e119fb-2b0b-412c-bdb6-0eb638b7a8d6","originalAuthorName":"李永峰"},{"authorName":"周晶钟","id":"e5e67691-ece2-4a3d-af94-772226b33fbd","originalAuthorName":"周晶钟"},{"authorName":"张明","id":"d35f4b5e-2b3f-459d-82e7-d5106a41382e","originalAuthorName":"张明"},{"authorName":"侯永亮","id":"25353deb-3fe6-445e-a6d7-cf45043ba94a","originalAuthorName":"侯永亮"}],"doi":"","fpage":"75","id":"7ead95a2-d91b-4716-98cf-f3a8b8bc5219","issue":"5","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":"75e84b37-6358-4f17-8e1a-020910eb7f05","keyword":"海绵锆","originalKeyword":"海绵锆"},{"id":"36d7ea37-f925-43dc-b7f2-d46699e2da5b","keyword":"燃烧合金","originalKeyword":"燃烧合金"},{"id":"3bf388f6-3840-4ab0-8c34-d1c24073df4f","keyword":"铁含量","originalKeyword":"铁含量"},{"id":"03095c74-5dba-4ac2-bc79-fa571e30547b","keyword":"颗粒制备","originalKeyword":"颗粒制备"},{"id":"36d1e4d8-a87e-405a-9a18-991d52da3351","keyword":"颗粒形貌","originalKeyword":"颗粒形貌"}],"language":"zh","publisherId":"bqclkxygc201505021","title":"铁含量对弹用燃烧合金颗粒制备的影响","volume":"38","year":"2015"},{"abstractinfo":"采用650 kVA的电弧炉,探讨了两步法冶炼高钒铁的可行性.认为:控制合适的富渣量是问题的关键.并且两步法冶炼高钒铁能使钒的回收率提高到97.28%,与一步法冶炼高钒铁相比提高约1.8%.","authors":[{"authorName":"孙朝晖","id":"e4da3fe1-dcb2-46bc-98a0-a15b950efc17","originalAuthorName":"孙朝晖"},{"authorName":"杨仰军","id":"e7d61bf1-62dc-4c32-b9ac-995dd52f31f1","originalAuthorName":"杨仰军"},{"authorName":"张帆","id":"28575375-f0ac-426f-8922-5c4acb01e2e8","originalAuthorName":"张帆"}],"doi":"","fpage":"1","id":"a4f6a138-f0d8-4bba-8814-e06949e81c20","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":"83cc201d-17d2-417b-bb04-5b0e19462f76","keyword":"钒铁","originalKeyword":"钒铁"},{"id":"5196f87a-1c55-4c72-b65c-8b21cd46cc72","keyword":"电弧炉","originalKeyword":"电弧炉"},{"id":"17d24b76-3124-4f2b-aacb-0d54d2a393e6","keyword":"两步法","originalKeyword":"两步法"},{"id":"1421c8a9-dfd8-41c7-b2dc-95bcf50c1514","keyword":"富渣","originalKeyword":"富渣"}],"language":"zh","publisherId":"gtft201001001","title":"两步法冶炼高钒铁技术探讨","volume":"31","year":"2010"},{"abstractinfo":"分析了攀宏公司高钒铁冶炼炉渣的特点,对高钒铁冶炼的炉渣形态进行了初步探讨,研究了高钒铁炉渣一些理化性能对冶炼工艺参数、冶炼技术经济指标的影响.","authors":[{"authorName":"王永刚","id":"c3514ab0-831f-4690-8e49-fff1b131939e","originalAuthorName":"王永刚"},{"authorName":"杨烽","id":"63abf6a2-d413-40eb-b0ee-ab5699d90e58","originalAuthorName":"杨烽"},{"authorName":"张建辉","id":"99c4420c-9035-4e01-9d9d-7fb39c937964","originalAuthorName":"张建辉"}],"doi":"10.3969/j.issn.1004-7638.2002.01.005","fpage":"21","id":"4efb754b-d0c1-4f00-a2ab-5883105932e1","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":"9216f5a8-96e9-4d68-a483-6d8807da2283","keyword":"高钒铁","originalKeyword":"高钒铁"},{"id":"5bbc9170-29d5-4513-bc36-9342182a658e","keyword":"炉渣","originalKeyword":"炉渣"},{"id":"4c4800a5-0f77-4e3f-8637-76908ecbc223","keyword":"组成","originalKeyword":"组成"},{"id":"c5aed7d5-dcca-4097-a24b-92d01297c9d6","keyword":"理化性能","originalKeyword":"理化性能"}],"language":"zh","publisherId":"gtft200201005","title":"高钒铁冶炼的渣态研究","volume":"23","year":"2002"},{"abstractinfo":"为回收利用钒铁冶炼的贫渣和处理还原沉钒后的废水,将钒铁冶炼过程中产生的贫渣经过风化、筛分粒度小于5 mm后获得贫渣灰,将其代替石灰粉末处理提钒过程中还原沉钒后的废水,pH值控制在7.0 ~8.5.结果表明:废水中每公斤铬消耗贫渣灰9.2kg,为石灰粉末用量的1.4倍,外排废水总铬小于1.5 mg/L,总钒小于1 mg/L,SS小于70 mg/L,pH值6~9,处理后的废水符合钒工业污染物排放标准GB26452-2011排放限值.以年产钒铁(FeV50)2 000 t计,每年可减少钒铁冶炼废渣排放量3000t以上.","authors":[{"authorName":"庄立军","id":"7c66e99f-01b2-4788-8089-aa7b23563eb3","originalAuthorName":"庄立军"},{"authorName":"王良","id":"120ff818-5516-455e-b6d7-d78ce3ac4b7b","originalAuthorName":"王良"},{"authorName":"赵华","id":"4e3f4eec-c6e4-428c-b789-f7402623ca7a","originalAuthorName":"赵华"},{"authorName":"滕晓慧","id":"8c16b2d7-28c4-4f92-8cd5-28dfa40a5675","originalAuthorName":"滕晓慧"},{"authorName":"马锦红","id":"ce6a1fca-5f2c-4e2d-ab01-863ddd1c2c10","originalAuthorName":"马锦红"}],"doi":"10.7513/j.issn.1004-7638.2014.01.013","fpage":"64","id":"96e2e415-d94e-4aab-b40c-896ac83112e4","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":"8b2ea45c-e580-479c-8e0d-08152081c42b","keyword":"钒铁冶炼","originalKeyword":"钒铁冶炼"},{"id":"6b2c2900-048f-4c33-b8e1-f2019902d2b8","keyword":"贫渣","originalKeyword":"贫渣"},{"id":"0a5c232c-1b3e-46e7-922f-58ec3057f43d","keyword":"沉钒废水","originalKeyword":"沉钒废水"},{"id":"bda5ba8b-7994-444d-b80a-21b28a52106b","keyword":"还原","originalKeyword":"还原"},{"id":"cd41cf60-1092-43f8-9b50-9169fbb315eb","keyword":"六价铬","originalKeyword":"六价铬"},{"id":"72234626-38a6-474e-b56c-d1aaaca56127","keyword":"中和沉淀","originalKeyword":"中和沉淀"}],"language":"zh","publisherId":"gtft201401013","title":"用钒铁冶炼贫渣处理还原沉钒后的废水","volume":"35","year":"2014"},{"abstractinfo":"以VzO5为原料,铝粒为还原剂,采用炉外法还原制取了高钒铁,并对工艺参数进行了研究,达到了提高钒回收率的目的.研究结果表明,高钒铁的回收率随还原剂铝用量的增加而增大,其用量以过量2%(质量分数,下同)为宜.分别试验了3种不同的精炼剂(纯铝粒、铝硅铁合金和铝钙铁合金)对钒回收率的影响,发现以AlCaFe作为精炼剂,钒的回收率明显增加,是较好的精炼剂.铝热法生产高钒铁时,铝粒的合适粒度为3~4 mm.","authors":[{"authorName":"郑溪娟","id":"76018638-70a7-4226-a508-cdae9edfc916","originalAuthorName":"郑溪娟"},{"authorName":"彭可武","id":"4697c116-9ae9-48bf-b785-68d4c137cf64","originalAuthorName":"彭可武"},{"authorName":"蒲年文","id":"c424ca81-c3c0-4bda-a311-524cfcfeb195","originalAuthorName":"蒲年文"},{"authorName":"马贺利","id":"37b5755b-eabe-4d8a-90d9-7c2bcd7dd54d","originalAuthorName":"马贺利"},{"authorName":"施虎","id":"97d8c2a0-d440-4165-8018-23f7d2abb9d6","originalAuthorName":"施虎"}],"doi":"","fpage":"6","id":"11bb9379-4a4a-4337-9381-dbf4fb4278e6","issue":"9","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":"bd49bf88-1247-431d-8e9b-83b273fe3fd5","keyword":"炉外法","originalKeyword":"炉外法"},{"id":"51c3a1a2-8117-4c99-b270-28d0e64f64e5","keyword":"高钒铁","originalKeyword":"高钒铁"},{"id":"5c15f3c4-cb7f-4a62-a379-ed6da8a06af2","keyword":"铝热法","originalKeyword":"铝热法"},{"id":"7af699ec-f482-4b64-8ac2-56443ea23fa7","keyword":"精炼剂","originalKeyword":"精炼剂"}],"language":"zh","publisherId":"gtyjxb201209002","title":"炉外法冶炼高钒铁的工艺参数","volume":"24","year":"2012"},{"abstractinfo":"以V2O5为原料,铝粒为还原剂,采用炉外法还原制取了高钒铁,并对工艺参数进行了研究,达到了提高钒回收率的目的。研究结果表明,高钒铁的回收率随还原剂铝用量的增加而增大,其用量以过量2%(质量分数,下同)为宜。分别试验了3种不同的精炼剂(纯铝粒、铝硅铁合金和铝钙铁合金)对钒回收率的影响,发现以AlCaFe作为精炼剂,钒的回收率明显增加,是较好的精炼剂。铝热法生产高钒铁时,铝粒的合适粒度为3~4mm。","authors":[{"authorName":"郑溪娟,彭可武","id":"f875a826-4d3e-4574-b658-b0be7ea9af6e","originalAuthorName":"郑溪娟,彭可武"},{"authorName":",蒲年文,马贺利,施虎","id":"2c6d5cf0-c344-4695-ac85-50ad9438a6fb","originalAuthorName":",蒲年文,马贺利,施虎"}],"categoryName":"|","doi":"","fpage":"6","id":"9f1849b7-e06a-417d-bb7c-b51ffc76c14e","issue":"9","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":"660a43f8-3746-4ee7-a11f-5a357b42111e","keyword":"炉外法 ","originalKeyword":"炉外法 "},{"id":"8b264c5c-fb62-44fb-8c1d-9662ab276d0a","keyword":" high vanadium ferrovanadium ","originalKeyword":" high vanadium ferrovanadium "},{"id":"2f3e7601-c02d-4389-b800-87e5d7d4cd30","keyword":" thermite method ","originalKeyword":" thermite method "},{"id":"11671268-6f9d-4cd9-a5ae-c8ac24efa525","keyword":" refine agent","originalKeyword":" refine agent"}],"language":"zh","publisherId":"1001-0963_2012_9_11","title":"炉外法冶炼高钒铁的工艺参数","volume":"24","year":"2012"},{"abstractinfo":"高铬型钒渣钠化焙烧-水浸-沉钒后获得了酸性铬溶液,为了生产合格的铬化工产品,必须除去其中的钒.采用硫酸铁为除钒试剂,研究了铁盐加入量、反应温度和pH值等因素对除钒效率的影响.结果表明,当铁盐添加量为9(以Fe/V摩尔比计)、反应温度80℃、反应终点pH为6~7时,除钒率可达97%,铬溶液中残留钒浓度小于0.08 g/L,铬损失率小于3.7%,能够满足后续生产重铬酸钠或三氧化二铬产品的要求.","authors":[{"authorName":"李信","id":"5e40a41d-ded7-4e55-83ec-b8e89839f180","originalAuthorName":"李信"},{"authorName":"李明","id":"2c5138b8-4ccf-43cb-8bcd-4d527018f608","originalAuthorName":"李明"},{"authorName":"梁斌","id":"fe3d7789-6922-4247-b02e-9fd3ddc905ab","originalAuthorName":"梁斌"}],"doi":"10.7513/j.issn.1004-7638.2016.04.004","fpage":"20","id":"7951147e-5e36-48c5-b201-9d19e0790d49","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":"4c60b7c4-22cf-45b9-9e0a-a300993a99d3","keyword":"钒铬溶液","originalKeyword":"钒铬溶液"},{"id":"7c9bc44e-8a1e-466f-92a1-920cd5a2ed2b","keyword":"铬产品","originalKeyword":"铬产品"},{"id":"296f1c33-d490-4653-b71b-3577a071c10c","keyword":"硫酸铁","originalKeyword":"硫酸铁"},{"id":"d600e0a7-0054-4d43-9493-57e69f4a1bdd","keyword":"除钒","originalKeyword":"除钒"},{"id":"a8ce17fc-1bee-4a71-92e5-c33b8d26e728","keyword":"吸附","originalKeyword":"吸附"}],"language":"zh","publisherId":"gtft201604004","title":"利用硫酸铁除去沉钒后酸性铬溶液中钒的试验研究","volume":"37","year":"2016"},{"abstractinfo":"研究了适用于倾翻炉一步法和两步法钒铁冶炼过程混合钒氧化物铝热反应的冶炼特性.考察不同钒氧化物配比、不同配铝系数对渣中钒损及单炉冶炼效率的影响.结果表明:V2O3的增加能够有效降低平衡态渣中钒含量,但不利于提高单炉冶炼效率,原料配比(罐数比)从0∶8提高到6∶2时,渣中钒含量从2.23%降低至1.85%,单炉渣量减少19.7%,单炉冶炼时间从180 min增加到194 min;两步法冶炼过程中,随着配铝系数提高到1.20,贫渣钒含量从一步法钒铁冶炼的1.85%降低至0.44%,渣中平均钒含量降低至0.88%;贫渣时间从194 min减少至146m in,精炼时间则从0增加到94 min,单炉冶炼周期较一步法延长46 min;最优试验条件下,合金产品中钒含量提高到51.6%,铝含量降低到低于0.3%的水平,在提高合金品质的同时也提高了铝的利用率.","authors":[{"authorName":"余彬","id":"f5761c00-82c2-4747-9490-bab26708f2f5","originalAuthorName":"余彬"},{"authorName":"鲜勇","id":"5adfacff-34c2-4033-8934-ed721fe0abc5","originalAuthorName":"鲜勇"},{"authorName":"孙朝晖","id":"6f744c4b-a268-4246-b57e-533513f5ed3a","originalAuthorName":"孙朝晖"},{"authorName":"景涵","id":"f42f1a0f-2e39-4c33-bd96-1e24a5b1e9c4","originalAuthorName":"景涵"},{"authorName":"唐红建","id":"dd9d617a-2958-471e-81a6-5099823f1b22","originalAuthorName":"唐红建"},{"authorName":"杜光超","id":"03e1d51d-e4b9-40ee-a6d0-014d013324d9","originalAuthorName":"杜光超"}],"doi":"10.7513/j.issn.1004-7638.2015.04.001","fpage":"1","id":"ffa06c77-2b8e-46f1-83ff-811c45a2c09c","issue":"4","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"3e8081a0-16ea-4d3d-b041-60ec48d58d5f","keyword":"混合钒氧化物","originalKeyword":"混合钒氧化物"},{"id":"be691ff6-3c2e-4422-85ba-b501b4975261","keyword":"倾翻炉","originalKeyword":"倾翻炉"},{"id":"34d914b4-b439-4487-bdb2-15296c907eb8","keyword":"两步法","originalKeyword":"两步法"},{"id":"5ea6e826-5673-4878-9c03-98e277ebdd14","keyword":"钒铁冶炼","originalKeyword":"钒铁冶炼"}],"language":"zh","publisherId":"gtft201504001","title":"混合钒氧化物倾翻炉钒铁冶炼工艺研究","volume":"36","year":"2015"},{"abstractinfo":"采用具备顶底复吹功能的500 kg中频感应炉模拟复吹转炉铁水提钒工艺,研究吹炼终点钒在渣铁间的分配比;运用X射线衍射分析钒铁尖晶石的分子组成.试验结果表明:吹炼终点钒在渣铁间分配比Lv为1.8 ~2.8,且与渣中FeO含量相关.为了保证钒渣质量,降低钒渣中FeO含量,减少铁损,吹炼终点V的质量分数不宜过低.钒渣中钒铁尖晶石的分子式为FeO(Fe,V)2O3,表明钒渣中钒为+3价.吹炼初期钒渣中存在少量+2价钒,随着供氧量增加,+2价钒的数量逐渐减少.","authors":[{"authorName":"刘质斌","id":"4dda2618-dbb8-430c-83cb-681d2859eb3a","originalAuthorName":"刘质斌"},{"authorName":"张曦东","id":"92bc3f04-ff97-48ae-ae0b-b2c106e1f552","originalAuthorName":"张曦东"},{"authorName":"马登","id":"40baed82-c5c9-45f7-9cbe-9d38e6fb4074","originalAuthorName":"马登"},{"authorName":"赵斌","id":"a5033880-5512-4b9f-bd64-b709ad409150","originalAuthorName":"赵斌"},{"authorName":"吴巍","id":"97b08f90-e0d8-4f70-ae32-ebbaa532868d","originalAuthorName":"吴巍"}],"doi":"10.7513/j.issn.1004-7638.2016.04.005","fpage":"25","id":"9318459c-319d-4f4f-bb15-e8c88af5aefb","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":"7d1805d5-6847-423e-95eb-05b70afa9e37","keyword":"高钒铁水","originalKeyword":"高钒铁水"},{"id":"751455dc-1b9f-4c6d-9ad8-71f6835962bf","keyword":"钒分配比","originalKeyword":"钒分配比"},{"id":"d3f223dd-3b99-4cbf-9f45-957fac4c4471","keyword":"钒渣","originalKeyword":"钒渣"},{"id":"6e620132-d905-48c5-b0fd-9a2e7e3783de","keyword":"钒铁尖晶石","originalKeyword":"钒铁尖晶石"}],"language":"zh","publisherId":"gtft201604005","title":"吹炼终点钒在渣铁间的分配比及相分析","volume":"37","year":"2016"}],"totalpage":1358,"totalrecord":13579}