{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"利用高温熔滴炉模拟实际高炉软熔带的运行情况,探讨Al2O3对含钒钛高炉炉料的软化温度、熔化温度、最大压差等高温物理性能的影响.结果表明:Al2O3含量增加后炉料的软化开始温度(T10)和软化终了温度(T40)升高,软化区间(△T1)变窄;炉料的熔化开始温度(Ta)降低,滴落温度(Td)升高,熔化区间(△Tds)变宽;炉料的最大压差(△Pmax)升高,熔滴总特性值(S值)增大,熔滴性能变差.试验结果表明Al2O3含量的增加对炉料的熔滴性能产生了负效应.","authors":[{"authorName":"王福佳","id":"669357fa-8a12-461b-b21d-debf2f179126","originalAuthorName":"王福佳"},{"authorName":"吕庆","id":"d7ddbd42-f009-4cc5-a18c-41b49688071e","originalAuthorName":"吕庆"},{"authorName":"陈树军","id":"faf10837-c881-4d78-a22e-a2afe78a2477","originalAuthorName":"陈树军"}],"doi":"10.7513/j.issn.1004-7638.2016.01.019","fpage":"95","id":"6eb1bffc-f432-480f-8950-ff0411865bd5","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":"618b67b1-d68d-4ef5-98b7-019677ebdba5","keyword":"含钒钛高炉炉料","originalKeyword":"含钒钛高炉炉料"},{"id":"19f806f8-5edf-4832-9b3f-82629190b3ed","keyword":"熔滴性能","originalKeyword":"熔滴性能"},{"id":"80c4dd77-ebbd-476b-9fed-384bd8e7988b","keyword":"Al2O3","originalKeyword":"Al2O3"},{"id":"9b597b17-fe1c-4a0f-9c3f-467638656c34","keyword":"高温物理性能","originalKeyword":"高温物理性能"}],"language":"zh","publisherId":"gtft201601019","title":"Al2O3对含钒钛高炉炉料熔滴性能的影响","volume":"37","year":"2016"},{"abstractinfo":"利用高温熔滴炉模拟实际高炉软熔带的运行情况,探讨承钢炉料结构条件下,不同碱度对含钒钛高炉炉料软化温度、熔化温度、最大压差、熔滴综合指标等高温物理性能的影响.试验结果表明:碱度在1.38 ~1.68变化时,随着碱度的升高炉料软化开始温度(T10)升高,由1 180℃升高到1 197℃;软化区间(△T1)变窄,由197℃下降到124℃.熔化开始温度(Ts)升高,由1 240℃升高到1 263℃;熔化区间(△Tds)变窄,由175℃下降到134℃.最大压差(△Pmax)降低,由14.70 kPa降低到8.71 kPa,料层透气性得到改善.熔滴综合指标(S值)降低,由1 301 kPa·℃降低到638 kPa·℃,炉料熔滴性能变好.当碱度超过1.68后炉料部分熔滴性能指标变差,因此碱度1.68是承钢现有炉料结构条件下最适宜的碱度.","authors":[{"authorName":"王福佳","id":"2e4fe09a-d775-4506-8342-33cbf5f37fcb","originalAuthorName":"王福佳"},{"authorName":"吕庆","id":"bf2320c4-2053-4901-adb9-2448a335aa5c","originalAuthorName":"吕庆"},{"authorName":"陈树军","id":"6887a1b2-616e-42ad-83ab-b71e96ccb76f","originalAuthorName":"陈树军"},{"authorName":"刘然","id":"c38b8534-38fd-47fe-813c-9f65777a8795","originalAuthorName":"刘然"},{"authorName":"李福民","id":"469f6c2d-d370-4554-9a30-33307a94b5ce","originalAuthorName":"李福民"}],"doi":"10.7513/j.issn.1004-7638.2015.05.018","fpage":"92","id":"8c736408-083d-4269-a651-b6fd30794443","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":"a5f895b6-1ff4-4065-8332-5c2f440fa18d","keyword":"高炉","originalKeyword":"高炉"},{"id":"997a5db7-a374-445b-99d2-02cb0edcba62","keyword":"钒钛炉料","originalKeyword":"钒钛炉料"},{"id":"a0b93d76-c493-45be-88bc-aaecda334c05","keyword":"熔滴性能","originalKeyword":"熔滴性能"},{"id":"5bd9d7d0-fee8-4490-ae87-8527db603ee2","keyword":"碱度","originalKeyword":"碱度"}],"language":"zh","publisherId":"gtft201505018","title":"碱度对含钒钛高炉炉料熔滴性能的影响","volume":"36","year":"2015"},{"abstractinfo":"利用高温熔滴炉模拟实际高炉软熔带的运行情况,探讨CaF2和MgO加入炉料后,对钒钛高炉炉料透气性、软熔带厚度、压差陡升温度、软熔区间、熔融区间等炉料高温物理性能的影响;为改善软熔带透气性,找出高炉合适软熔带位置,从而达到解决利用钒钛磁铁矿带来的不利影响的目的,为提高高炉强化冶炼目的提供重要依据.结果表明:炉料中添加萤石后对软化开始温度基本无明显影响,但使软化温度区间变窄,初渣带位置形成过早,软熔带厚度、最大压差、总特性值都升高.MsO的加入使软化开始温度升高,软化温度区间变窄,说明MgO的加入使软熔带位置下移,软熔带变薄.","authors":[{"authorName":"崔世强","id":"81e58ff3-0f0a-4064-b7d0-bccb2e24d753","originalAuthorName":"崔世强"},{"authorName":"吕庆","id":"659ed23a-8532-4284-ab54-7d3971340d15","originalAuthorName":"吕庆"}],"doi":"10.7513/j.issn.1004-7638.2014.01.015","fpage":"74","id":"c4e62401-fb7f-4b68-86ce-8f49bd2228e6","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":"c15940cb-7c55-458b-9a52-a1eb1bb0ab3e","keyword":"熔滴性能","originalKeyword":"熔滴性能"},{"id":"c7fc6f50-33b0-4c5c-a034-331a3f4bc85b","keyword":"萤石","originalKeyword":"萤石"},{"id":"af34546b-7f5c-4abf-920b-e41a32b3ce0a","keyword":"MgO","originalKeyword":"MgO"},{"id":"fa88c94f-f7be-4ea8-9d68-4b27e0d2e441","keyword":"冶金性能","originalKeyword":"冶金性能"}],"language":"zh","publisherId":"gtft201401015","title":"萤石和氧化镁对含钒钛高炉炉料熔滴性能的影响","volume":"35","year":"2014"},{"abstractinfo":"利用高温熔滴炉模拟实际高炉软熔带的运行情况,探讨TO2/SiO2对含钒钛高炉炉料的软化温度、熔化温度、最大压差等高温物理性能的影响.试验结果表明:TiO2/SiO2比值由0.17增大到0.43后,炉料的软化开始温度(T10)升高了56℃,软化终了温度(T40)升高了35℃,说明软熔带位置较低;炉料的熔化开始温度(Ts)升高了40℃,滴落温度(Td)升高了30℃;炉料的最大压差(△Pmax)升高,炉料透气性变差;炉料熔滴的总特性值(S值)增大,熔滴性能变差.试验范围内随着TiO2/SiO2比值的增大炉料的熔滴性能变差,建议在承钢现有炉料结构条件下,应适当降低TiO2/SiO2比值.","authors":[{"authorName":"王福佳","id":"531e1a2e-bf60-4c84-a0ce-77e3dee3cf78","originalAuthorName":"王福佳"},{"authorName":"吕庆","id":"1c0214a5-c304-4166-9f93-f5b9a2a88434","originalAuthorName":"吕庆"},{"authorName":"陈树军","id":"d01c7870-711e-49d0-9957-f0715b545145","originalAuthorName":"陈树军"}],"doi":"10.7513/j.issn.1004-7638.2015.06.015","fpage":"79","id":"02736cf6-f169-40b1-b5cf-ca2cd15d02a8","issue":"6","journal":{"abbrevTitle":"GTFT","coverImgSrc":"journal/img/cover/gtft1.jpg","id":"28","issnPpub":"1004-7638","publisherId":"GTFT","title":"钢铁钒钛"},"keywords":[{"id":"11ea3ded-245b-42da-991e-cd1c67f5c5a2","keyword":"高炉","originalKeyword":"高炉"},{"id":"d7882704-d1d4-4cc6-a188-994516760cfd","keyword":"含钒钛炉料","originalKeyword":"含钒钛炉料"},{"id":"d034be12-5c42-4ae2-b43e-bc9746cd3afc","keyword":"熔滴性能","originalKeyword":"熔滴性能"},{"id":"6c4efaae-2d08-445e-9410-ac9861b25755","keyword":"TiO2/SiO2","originalKeyword":"TiO2/SiO2"}],"language":"zh","publisherId":"gtft201506015","title":"TiO2/SiO2对含钒钛高炉炉料熔滴性能的影响","volume":"36","year":"2015"},{"abstractinfo":"利用高温熔滴炉模拟实际高炉软熔带的运行情况.探讨在承钢炉现有炉料结构条件下,炉料中不同Mg O含量对含钒钛高炉炉料软化温度、熔化温度、最大压差、熔滴综合指标等高温物理性能的影响.结果表明:Mg O质量分数由1.92%增加到2.40%后,炉料的软化温度无明显变化;炉料的滴落温度td 升高,熔化温度区间Δtds增大;炉料的最大压差ΔPmax升高,炉料透气性变差;炉料熔滴的总特性值S增大,熔滴性能变差.","authors":[{"authorName":"吕庆","id":"11ae8903-c3f7-41bf-9270-aa39dea84066","originalAuthorName":"吕庆"},{"authorName":"王福佳","id":"97796ecf-4b49-4a98-9577-849f82ff4e6c","originalAuthorName":"王福佳"},{"authorName":"陈树军","id":"e271fbe9-dbdf-4992-a422-0d1c2871541c","originalAuthorName":"陈树军"}],"doi":"10.13228/j.boyuan.issn1001-0963.20150206","fpage":"24","id":"3503e3c3-de1c-4282-930b-6dc1c10ed99b","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":"b262f6a2-fb1c-4a42-8edf-40b6ba417b2c","keyword":"熔滴性能","originalKeyword":"熔滴性能"},{"id":"55e5899f-7250-4784-ba50-6924ae99bb28","keyword":"Mg O","originalKeyword":"Mg O"},{"id":"def791e4-3875-439b-80b6-131c1396ebb0","keyword":"高温物理性能","originalKeyword":"高温物理性能"}],"language":"zh","publisherId":"gtyjxb201609005","title":"烧结矿MgO含量对含钒钛炉料熔滴性能影响","volume":"28","year":"2016"},{"abstractinfo":"高炉炼铁正朝着高产、低污染、低能耗的方向发展,为了实现这一目标,包括高炉使用含碳复合炉料等一些革新的炼铁技术已经被提出或实际应用。铁焦、热压含碳球团是将铁矿粉和煤粉按一定比例混合后制成的新型含碳复合炉料。研究结果指出,含碳复合炉料相比于传统的高炉炉料(烧结矿和球团矿)具有高温强度高、还原性能好以及原料适应性强等优势。阐明了高炉使用含碳复合炉料的基本原理,介绍了铁焦制备的工艺流程及应用情况,重点进行了热压含碳球团制备工艺流程、冷态冶金性能、高温冶金性能、高炉使用热压含碳球团等试验研究,最后利用多流体高炉数学模型对高炉使用热压含碳球团操作进行了模拟研究。研究表明,高炉使用一定量的含碳复合炉料可以降低热空区温度,增加产量,降低焦比,高炉热利用效率明显提高,操作性能得到有效改善。","authors":[{"authorName":"储满生","id":"ab042587-5ddc-4029-8c0f-8307f022ba16","originalAuthorName":"储满生"},{"authorName":"赵伟","id":"0b8b8db3-8c0c-4fb7-9bcf-0b007724420e","originalAuthorName":"赵伟"},{"authorName":"柳政根","id":"8adb4bb4-0618-4548-b940-3e88a907831a","originalAuthorName":"柳政根"},{"authorName":"王宏涛","id":"ae72f70c-283c-4935-a388-5af70501ff42","originalAuthorName":"王宏涛"},{"authorName":"唐珏","id":"865145cc-994e-45e0-ad28-0e03f2c7c8ed","originalAuthorName":"唐珏"}],"doi":"10.13228/j.boyuan.issn0449-749x.20140240","fpage":"9","id":"65765b48-ebe5-40dd-914d-1d8c35c7b739","issue":"3","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"4790289f-e14a-447e-95b4-bea216c5398d","keyword":"高炉炼铁","originalKeyword":"高炉炼铁"},{"id":"509bf767-707d-4654-8be0-6b9d683b50eb","keyword":"含碳复合炉料","originalKeyword":"含碳复合炉料"},{"id":"9b41d84e-02c7-4bbf-a15d-daa96e171be7","keyword":"铁焦","originalKeyword":"铁焦"},{"id":"f8a8d8f2-34d8-4c5a-8d02-68c4241d2986","keyword":"热压含碳球团","originalKeyword":"热压含碳球团"},{"id":"645191f7-cfae-4bad-af95-6a430c2dde4d","keyword":"CO2减排","originalKeyword":"CO2减排"}],"language":"zh","publisherId":"gt201503003","title":"高炉使用含碳复合炉料的原理","volume":"","year":"2015"},{"abstractinfo":"采用高温固相法,掺杂不同质量分数的V_2O_5,在800℃煅烧2h合成了钒掺杂的含钛高炉渣催化剂(vanadium oxide modified titanium bearing blast furnace slag,VTBBFS).用X射线衍射、扫描电子显微镜和紫外-可见漫反射光谱仪对钒掺杂的含钛高炉渣催化剂进行了表征,确定其具有钙钛矿结构;粉体的颗粒形态均为不规则块状,800℃煅烧后出现了团聚现象;在紫外区域具有强光吸收能力,并发生红移.以白色念珠菌为实验菌种考察钒掺杂的含钛高炉渣催化剂抗真菌能力.结果表明,V_2O_5掺杂量为10%时,催化剂具有较强的抗白色念珠菌能力,在普通光照下杀菌率可达到100%.","authors":[{"authorName":"王辉","id":"6eff59b2-1e5e-47d4-b375-0cbae6fcd692","originalAuthorName":"王辉"},{"authorName":"薛向欣","id":"6f774ca7-9ddc-4ec5-99ec-d87239e1dfb7","originalAuthorName":"薛向欣"},{"authorName":"杨合","id":"217c5ef7-01bd-4243-8407-ec8d946ca72b","originalAuthorName":"杨合"},{"authorName":"李述贤","id":"31c04bd9-67b8-47a2-9770-ec79919bbafa","originalAuthorName":"李述贤"}],"doi":"","fpage":"414","id":"89e27175-b1d5-49f2-af9a-4705c43c125b","issue":"3","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"34d7406a-e745-46f8-b821-b9d84003b22b","keyword":"钒掺杂含钛高炉渣","originalKeyword":"钒掺杂含钛高炉渣"},{"id":"b98958f0-72e3-4460-9fc5-1f8665605749","keyword":"钙钛矿","originalKeyword":"钙钛矿"},{"id":"edb285b8-6d1d-49ab-9233-c172424ecce0","keyword":"光催化","originalKeyword":"光催化"},{"id":"580d9e7a-78db-4fef-994b-1cd8ff348407","keyword":"抗菌性能","originalKeyword":"抗菌性能"}],"language":"zh","publisherId":"gncl201003014","title":"高温固相法制备钒掺杂含钛高炉渣光催化抗菌材料","volume":"41","year":"2010"},{"abstractinfo":"为提高高炉冶炼钒钛磁铁矿水平,系统研究了矿焦混装对高炉综合炉料软熔滴落性能和V、Cr在渣铁中迁移规律的影响,并进行了理论分析。试验过程中烧结矿和球团矿所占比例不变。研究表明,矿焦混装对高炉综合炉料的软化区间、熔化区间、滴落率和透气性等软熔滴落性能参数有显著影响。随着混装率提高,软化区间t40-t4稍微变宽;熔化区间tD-tS逐渐变窄,软熔带变薄且位置下移;熔滴性能总特征值明显减小,综合炉料透气性能显著改善;渣铁滴落率先增加后减少;V、Cr在初铁中的收得率先升高后降低。因此,一定程度的矿焦混装有利于改善钒钛磁铁矿高炉冶炼综合炉料的软熔滴落性能,其混装率以25%为宜。","authors":[{"authorName":"陈立杰","id":"1d404b90-9897-4368-9292-873d465e0e71","originalAuthorName":"陈立杰"},{"authorName":"柳政根","id":"b03fe4d6-6938-4c26-bf9d-08369ae39c41","originalAuthorName":"柳政根"},{"authorName":"付小佼","id":"6e2b1126-815c-4e24-b828-c055b77450b3","originalAuthorName":"付小佼"},{"authorName":"于洪翔","id":"b77c9070-9bd8-4672-8564-bbdba7db4e4f","originalAuthorName":"于洪翔"},{"authorName":"唐珏","id":"cb0ca887-daf9-4a40-8065-84c3dc82afcd","originalAuthorName":"唐珏"},{"authorName":"储满生","id":"45b1d427-4ef4-4133-a425-b52cea6e300d","originalAuthorName":"储满生"}],"doi":"10.13228/j.boyuan.issn0449-749x.20140042","fpage":"5","id":"8731e59c-2699-4d6e-b513-a5b16ad59cb2","issue":"1","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"013eab0a-bbbb-4595-bb2b-d5b92eafe56d","keyword":"钒钛磁铁矿","originalKeyword":"钒钛磁铁矿"},{"id":"3bdad2d7-5db9-4efa-a87d-5e25d7810fa8","keyword":"高炉炼铁","originalKeyword":"高炉炼铁"},{"id":"cdad8bba-b12a-4913-a094-6c25785a51f7","keyword":"矿焦混装","originalKeyword":"矿焦混装"},{"id":"b5d4c95b-d623-4d20-96ac-a63d28d9dc9d","keyword":"软熔滴落性能","originalKeyword":"软熔滴落性能"},{"id":"13a48971-30ee-484a-b85a-b227069dfe52","keyword":"V","originalKeyword":"V"},{"id":"dcc7f013-66b5-43b1-9a27-e5e4e18778bd","keyword":"Cr还原","originalKeyword":"Cr还原"}],"language":"zh","publisherId":"gt201501002","title":"矿焦混装对钒钛矿综合炉料软熔滴落的影响","volume":"","year":"2015"},{"abstractinfo":"对宣钢高炉炉料结构进行了熔滴性能试验研究.单矿的熔滴试验结果表明:宣钢常用的2种烧结矿软化性能较好,但滴落性能较差,1 520℃仍未滴落;3种球团矿中自产球总体熔滴指标最好但软化区间最长(313℃);2种块矿中PB矿开始软化温度最低软熔区间最长,试验中未能滴落.蒙古矿软熔性能较好,但滴落温度高达1 518℃.通过对15种配矿方案进行的熔滴试验,结果表明:降低烧结矿配比,提高PB矿比例可改善炉料的熔滴性能.在试验条件下,配矿方案为\"烧结矿68%+球团矿16% +PB矿16%\"的炉料结构熔滴性能最佳.","authors":[{"authorName":"赵晓杰","id":"37538f4d-ef50-42bb-8737-67350eb26bdf","originalAuthorName":"赵晓杰"},{"authorName":"刘然","id":"c861fb41-830b-4181-a805-f2b0933e0fe6","originalAuthorName":"刘然"},{"authorName":"李豪杰","id":"653e6909-a052-43c3-8bba-701e6f30dbcf","originalAuthorName":"李豪杰"}],"doi":"10.7513/j.issn.1004-7638.2016.01.029","fpage":"148","id":"7f402b7f-3940-4ec2-b20e-0e48d56200ee","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":"db243ba2-0aec-4a29-a84d-085e276f9096","keyword":"高炉","originalKeyword":"高炉"},{"id":"625b0962-ceb8-484c-9d49-2880866efb19","keyword":"含铁炉料","originalKeyword":"含铁炉料"},{"id":"1bf8de8f-5454-41c2-aaeb-ed409257d02c","keyword":"熔滴性能","originalKeyword":"熔滴性能"},{"id":"69eb5e2c-b069-4186-979a-0f0169f3c850","keyword":"烧结矿","originalKeyword":"烧结矿"},{"id":"2343b8e5-40f0-432c-9bb2-df582e9d50ff","keyword":"球团矿","originalKeyword":"球团矿"},{"id":"b5d108dc-5f7e-4800-be13-67fbb3d18ecd","keyword":"块矿","originalKeyword":"块矿"}],"language":"zh","publisherId":"gtft201601029","title":"宣钢高炉含铁炉料熔滴性能","volume":"37","year":"2016"},{"abstractinfo":"以高钛型钒钛磁铁矿为主要原料的攀钢高炉,在解决了泡沫渣、粘渣、铁水粘罐、铁损高、脱硫能力低等重要技术难题后,通过优化高炉操作及炉料结构,开发一系列强化冶炼的新技术,取得了大型高炉在采用难冶炼的特殊矿、入炉品位低的情况下达到高利用系数的经验,获得了巨大的经济效益,并建立了高炉冶炼钒钛磁铁矿的系统理论.","authors":[{"authorName":"马家源","id":"a853a0ab-578f-48b7-a10f-df0ca12ea940","originalAuthorName":"马家源"},{"authorName":"孙希文","id":"37a639bb-c10c-4901-ab4e-a72eadf66737","originalAuthorName":"孙希文"},{"authorName":"盛世雄","id":"be1c6ee0-2cb7-4482-a7f7-187544b760da","originalAuthorName":"盛世雄"}],"doi":"","fpage":"4","id":"3837e12b-0044-4a67-8c6e-1decfaf1feae","issue":"1","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"58a63000-93b2-42c9-9226-69890ed8eae1","keyword":"钒钛磁铁矿","originalKeyword":"钒钛磁铁矿"},{"id":"863a5d5e-a1d4-4a62-b1ed-f1d45658b99d","keyword":"高炉","originalKeyword":"高炉"},{"id":"6bea2b6c-ab27-471b-9cf7-82e60052ceb7","keyword":"强化冶炼","originalKeyword":"强化冶炼"}],"language":"zh","publisherId":"gt200001002","title":"钒钛磁铁矿高炉冶炼的强化","volume":"35","year":"2000"}],"totalpage":2374,"totalrecord":23736}