{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"采用真空感应炉浸棒法,在真空度为5 kPa,于1 650 ℃保温25 min的试验条件下研究了w(C)约为10%的MgO-C材料的抗熔渣侵蚀性;对试验后的试样进行观察与测量,并用SEM分析了侵蚀后试样显微结构.结果表明:在本试验条件下,熔渣的侵蚀速率大于MgO与C反应的脱碳速率,随着CaO-SiO<,2>渣系碱度的提高,MgO-C材料侵蚀量减少;MgO-C材料对CaO-Al<,2>O<,3>熔渣有较强的抗侵蚀性.","authors":[{"authorName":"王龙光","id":"ec9b98a3-19b9-435c-87f8-ec9d99fb5921","originalAuthorName":"王龙光"},{"authorName":"李红霞","id":"aa2d55f4-2707-46e6-9c0a-b32b96b747be","originalAuthorName":"李红霞"},{"authorName":"周会俊","id":"faf5ec08-cdd3-41c6-a3f9-d99551528833","originalAuthorName":"周会俊"},{"authorName":"刘鹏","id":"f4ba1332-b558-4fdb-a2c1-750af9e8cd2f","originalAuthorName":"刘鹏"},{"authorName":"娄海琴","id":"ac3d69ef-2af3-4ad6-b34e-0adc984b2702","originalAuthorName":"娄海琴"}],"doi":"10.3969/j.issn.1001-1935.2011.01.003","fpage":"11","id":"3846674f-3b28-47f0-a04a-16ed61ae1540","issue":"1","journal":{"abbrevTitle":"NHCL","coverImgSrc":"journal/img/cover/NHCL.jpg","id":"55","issnPpub":"1001-1935","publisherId":"NHCL","title":"耐火材料 "},"keywords":[{"id":"6ab800d9-e9f7-4fff-91df-46b966c180cf","keyword":"MgO-C材料","originalKeyword":"MgO-C材料"},{"id":"f9a104fc-23a0-4e69-b710-0431932e7aa4","keyword":"抗侵蚀","originalKeyword":"抗侵蚀"},{"id":"b63c090e-d2c4-4dc3-a7e8-6cd82b2c2984","keyword":"低压","originalKeyword":"低压"}],"language":"zh","publisherId":"nhcl201101003","title":"MgO-C材料低压动态条件下抗侵蚀性的研究","volume":"45","year":"2011"},{"abstractinfo":"以w(MgO) =98.5%的电熔镁砂和w(C)=99.3%的天然鳞片石墨为原料,酚醛树脂为结合剂,于900℃氢气气氛中炭化处理后制备了碳含量(w)分别为5%、10%、15%、20%、25%、30%的MgO-C材料,并考察碳含量对其抗氧化性(1 000、1 400℃下)和抗渣侵蚀性(1 650~1 700℃)的影响.结果表明:1)随着碳含量的增加,MgO-C试样的抗氧化性能提高;2)渣线部位试样的侵蚀量随着碳含量的增加先减少后增加,在碳含量为20%(w)时最小;钢液部位试样的侵蚀量随着碳含量的增加而增加,但当碳含量为25%(w)时急剧减少.","authors":[{"authorName":"张连振","id":"83ac0f62-d77c-4af2-adb9-42a5303127be","originalAuthorName":"张连振"},{"authorName":"杨鑫","id":"f25101b9-d04a-4f31-ad1b-ed2963b0be51","originalAuthorName":"杨鑫"}],"doi":"10.3969/j.issn.1001-1935.2015.02.019","fpage":"149","id":"a99a2fe0-7b61-45c4-beb6-49bed6a28f7c","issue":"2","journal":{"abbrevTitle":"NHCL","coverImgSrc":"journal/img/cover/NHCL.jpg","id":"55","issnPpub":"1001-1935","publisherId":"NHCL","title":"耐火材料 "},"keywords":[{"id":"116d6367-0eb6-490c-95a2-1ce8b80420cb","keyword":"MgO-C材料","originalKeyword":"MgO-C材料"},{"id":"7469c412-274f-4b28-8097-4520cf094d5f","keyword":"碳含量","originalKeyword":"碳含量"},{"id":"41f69381-2a05-461c-8644-01c31b00b72a","keyword":"抗氧化性","originalKeyword":"抗氧化性"},{"id":"e11cb63d-6277-4f7e-90d0-2a926b502a8f","keyword":"抗渣侵蚀性","originalKeyword":"抗渣侵蚀性"}],"language":"zh","publisherId":"nhcl201502019","title":"碳含量对MgO-C材料抗氧化性和抗渣侵蚀性的影响","volume":"49","year":"2015"},{"abstractinfo":"以电熔镁砂颗粒(5~3 min、3~1 mm、≤1 mm)、电熔镁砂细粉(≤0.088 mm)、鳞片石墨(≤0.15 mm)、矾土基β-SiAlON细粉(≤0.088 mm,气孔率28%,Z=2)为主要原料,配制成ω(鳞片石墨)+ω(矾土基β-SiAlON细粉)分别为12%+0、4%+6%、4%+9%和4%+12%的4组配料,采用酚醛树脂作结合剂,以180 MPa压力成型.经185℃10 h固化后,按相关标准检测了试样的体积密度、显气孔率、常温耐压强度、常温抗折强度、高温抗折强度、抗热震性、抗氧化性和抗渣性.结果表明:随着试样中ω(鳞片石墨)+ω(矾土基β-SiAlON细粉)按12%+0、4%+6%、4%+9%、4%+12%的顺序变化,试样的显气孔率有所上升,体积密度略有降低;试样的常温耐压强度、常温抗折强度、1 400℃高温抗折强度、抗热震性和抗氧化性均有不同程度的提高;抗渣侵蚀性以ω(鳞片石墨)+ω(矾土基β-SiAlON细粉)为4%+6%的试样略高,其他试样则有所降低.","authors":[{"authorName":"王京京","id":"d43d7912-a1b1-44c0-a9b1-73a73f4c56ad","originalAuthorName":"王京京"},{"authorName":"叶方保","id":"6b597119-cd5d-42e0-b47a-710c1a39c06c","originalAuthorName":"叶方保"},{"authorName":"马成良","id":"2e952eff-8cf6-4186-b0ba-d54c99e7f496","originalAuthorName":"马成良"},{"authorName":"钟香崇","id":"f5ec26c8-055f-4dc4-95c3-b404942b2f83","originalAuthorName":"钟香崇"}],"doi":"10.3969/j.issn.1001-1935.2008.05.003","fpage":"330","id":"245f88ba-c664-4e2c-99d6-176cde0b1331","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":"028df4d6-0831-403e-bc84-ef61d1ade28e","keyword":"β-SiAlON","originalKeyword":"β-SiAlON"},{"id":"0c1a375f-ea44-42ef-b27a-73156e72ba03","keyword":"MgO-C材料","originalKeyword":"MgO-C材料"},{"id":"1011e0f9-5524-4e11-b574-f55be1f99626","keyword":"抗氧化性","originalKeyword":"抗氧化性"},{"id":"e801a469-2b1b-420b-878a-5c284a0a28e0","keyword":"高温抗折强度","originalKeyword":"高温抗折强度"},{"id":"7393a3ac-8af1-4dca-ba13-cdea113d39e5","keyword":"抗渣性","originalKeyword":"抗渣性"}],"language":"zh","publisherId":"nhcl200805003","title":"β-SiAlON对MgO-C材料性能的影响","volume":"42","year":"2008"},{"abstractinfo":"以电熔镁砂和不同粒度的鳞片石墨(分别为100目、1000目和100目+1000目混合型)为主要原料,制备了低碳MgO-C材料,研究了鳞片石墨粒度对低碳镁碳耐火材料的物理性能、抗氧化性能、导热性能及热膨胀性能的影响.结果表明:不同粒度的混合型石墨作为碳源,可以有效改善低碳MgO-C材料的物理性能.综合各个温度试验结果,含有混合型石墨的试样抗氧化效果最好,含混合型石墨的试样热导率最大,只含1000目石墨的试样热导率最小,500℃以上含有混合型石墨的试样膨胀率最大.","authors":[{"authorName":"王志强","id":"48f5436a-3e0c-45bc-a7c3-59299fa99b3a","originalAuthorName":"王志强"},{"authorName":"朱伯铨","id":"4b9476d1-d2cb-4747-a463-4003c13cb37a","originalAuthorName":"朱伯铨"},{"authorName":"方斌祥","id":"2d41ffbf-6501-4e9a-a0d5-98ef1f7f6b0d","originalAuthorName":"方斌祥"},{"authorName":"周伦潮","id":"1e003c77-ac59-480b-99a7-83e702a360d1","originalAuthorName":"周伦潮"}],"doi":"","fpage":"139","id":"ec48c3c1-199c-48af-b2fb-b44e2c0b5e7d","issue":"9","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"467fb261-8f72-4f54-8932-63ab16ad6be1","keyword":"石墨粒度","originalKeyword":"石墨粒度"},{"id":"840eb73f-24ac-4ca7-bd17-bb51cb5a121b","keyword":"MgO-C材料","originalKeyword":"MgO-C材料"},{"id":"60961483-235e-47ee-b719-b4f251795185","keyword":"抗氧化性","originalKeyword":"抗氧化性"},{"id":"0b997ce6-f700-429a-8c43-87feb7e2faee","keyword":"热导率","originalKeyword":"热导率"},{"id":"62cf87c5-df2d-42e3-9c22-1938e54b7c7f","keyword":"线膨胀率","originalKeyword":"线膨胀率"}],"language":"zh","publisherId":"cldb200809038","title":"不同粒度的鳞片石墨对低碳镁碳耐火材料性能的影响","volume":"22","year":"2008"},{"abstractinfo":"为了弄清MgO-C耐火材料的损伤演化过程及破坏形式,利用声发射技术研究了MgO-C耐火材料受载破坏过程中的声发射现象,通过信号分析方法,对声发射信号功率谱的质心频率和声发射能量历程图进行了分析.结果表明:MgO-C耐火材料的受载破坏过程分为4个阶段,主要的损伤形式为基质损伤和界面损伤.","authors":[{"authorName":"赵尧杰","id":"913135d6-975d-4793-9724-6535de95effa","originalAuthorName":"赵尧杰"},{"authorName":"王志刚","id":"d7dbe681-c689-4bd4-91a8-1f428e46ce59","originalAuthorName":"王志刚"},{"authorName":"刘昌明","id":"eb8b5936-4d30-451f-8e53-899999850ba4","originalAuthorName":"刘昌明"},{"authorName":"韩兵强","id":"acea8ac4-0d46-460f-8b7c-99dcf7cde03a","originalAuthorName":"韩兵强"}],"doi":"10.3969/j.issn.1001-1935.2012.04.004","fpage":"254","id":"0a96d400-c0ba-42a1-b0f0-01188d8c4e2d","issue":"4","journal":{"abbrevTitle":"NHCL","coverImgSrc":"journal/img/cover/NHCL.jpg","id":"55","issnPpub":"1001-1935","publisherId":"NHCL","title":"耐火材料 "},"keywords":[{"id":"9dbf1721-1e50-43d9-97f5-01cade36040c","keyword":"镁碳质耐火材料","originalKeyword":"镁碳质耐火材料"},{"id":"7ec9b4e6-75ee-4866-ad4d-8e57c67efb30","keyword":"声发射","originalKeyword":"声发射"},{"id":"160b5c7b-e241-46a0-977a-beed47828029","keyword":"质心频率","originalKeyword":"质心频率"},{"id":"ec53536e-cf9b-4be2-8186-82aca2b667d2","keyword":"损伤演化","originalKeyword":"损伤演化"}],"language":"zh","publisherId":"nhcl201204004","title":"MgO-C耐火材料受载损伤过程的声发射特性研究","volume":"46","year":"2012"},{"abstractinfo":"以两种不同碳含量的MgO-C耐火材料为研究对象,对试验测得的抗折强度数据采用Weibull函数进行统计分析,并结合试样的断口形貌研究了MgO-C耐火材料的抗折强度分布规律.结果表明:MgO-C耐火材料的抗折强度服从Weibull分布;增大材料的致密度和石墨含量能够降低MgO-C耐火材料抗折强度的离散性,提高强度的可靠性.","authors":[{"authorName":"朱青友","id":"17f725d7-8859-4ee7-9d58-602da4284b25","originalAuthorName":"朱青友"},{"authorName":"员文杰","id":"cec39f81-2fdd-4f6c-b48f-41bb4a46432f","originalAuthorName":"员文杰"},{"authorName":"祝洪喜","id":"5b6fe301-3372-4b32-ac7e-4f7d7b8c754d","originalAuthorName":"祝洪喜"},{"authorName":"邓承继","id":"f1d3ba93-d847-4d19-8983-6c71a8794231","originalAuthorName":"邓承继"}],"doi":"","fpage":"344","id":"838f8805-4718-400a-8576-3db03cfdab85","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":"845f917c-f6f1-4d81-aa08-f2f517ee634b","keyword":"MgO-C耐火材料","originalKeyword":"MgO-C耐火材料"},{"id":"a3e47d4f-b222-4003-bbc9-908b6b158066","keyword":"抗折强度","originalKeyword":"抗折强度"},{"id":"a1cdcc10-c606-441d-a8ab-930abe3d07f2","keyword":"Weibull模量","originalKeyword":"Weibull模量"},{"id":"ee1eaec8-eadd-426e-9d85-fe2cd7accd15","keyword":"显微结构","originalKeyword":"显微结构"}],"language":"zh","publisherId":"nhcl201205007","title":"MgO-C耐火材料抗折强度分布规律的研究","volume":"46","year":"2012"},{"abstractinfo":"以两种不同碳含量的MgO-C耐火材料为研究对象,对试验测得的抗折强度数据采用Weibull函数进行统计分析,并结合试样的断口形貌研究了MgO-C耐火材料的抗折强度分布规律.结果表明:MgO-C耐火材料的抗折强度服从Weibull分布;增大材料的致密度和石墨含量能够降低MgO-C耐火材料抗折强度的离散性,提高强度的可靠性.","authors":[{"authorName":"朱青友","id":"dd0a6bce-a2bd-4c1b-bc67-f3a9547733ca","originalAuthorName":"朱青友"},{"authorName":"员文杰","id":"e7157708-0118-44f2-b160-16c39496ac6e","originalAuthorName":"员文杰"},{"authorName":"祝洪喜","id":"f12d3c7d-b0ee-49d1-bdea-f57c838c0d33","originalAuthorName":"祝洪喜"},{"authorName":"邓承继","id":"3a7f6656-8748-4f20-bb0d-7383c8deaa8d","originalAuthorName":"邓承继"}],"doi":"","fpage":"344","id":"ce39f237-71f3-4f00-8dfd-90ffebf5bc4e","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":"225ee5be-2248-4ab6-a6ad-6f24cefc65c7","keyword":"MgO-C耐火材料","originalKeyword":"MgO-C耐火材料"},{"id":"3a1bedf9-ad73-47b8-abae-75ea5e5e8d9b","keyword":"抗折强度","originalKeyword":"抗折强度"},{"id":"4361cf51-b727-4b11-8132-ba9637be850d","keyword":"Weibull模量","originalKeyword":"Weibull模量"},{"id":"64770706-e1ba-4fc3-8d20-6a77d1dad483","keyword":"显微结构","originalKeyword":"显微结构"}],"language":"zh","publisherId":"nhcl201205007","title":"MgO-C耐火材料抗折强度分布规律的研究","volume":"46","year":"2012"},{"abstractinfo":"以两种不同碳含量的MgO-C耐火材料为研究对象,对试验测得的抗折强度数据采用Weibull函数进行统计分析,并结合试样的断口形貌研究了MgO-C耐火材料的抗折强度分布规律.结果表明:MgO-C耐火材料的抗折强度服从Weibull分布;增大材料的致密度和石墨含量能够降低MgO-C耐火材料抗折强度的离散性,提高强度的可靠性.","authors":[{"authorName":"朱青友","id":"fdff5a11-eb88-4371-b8e9-cb8ef333b5b3","originalAuthorName":"朱青友"},{"authorName":"员文杰","id":"3fb5bd35-d732-45f0-b277-661018b0e939","originalAuthorName":"员文杰"},{"authorName":"祝洪喜","id":"315fdc91-3a51-4fe4-8c6b-a529416853e8","originalAuthorName":"祝洪喜"},{"authorName":"邓承继","id":"74d08fbd-e7c5-44e7-9d67-f34948131732","originalAuthorName":"邓承继"}],"doi":"","fpage":"344","id":"e2f26731-d4f0-4474-975c-c82f958ce3ba","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":"5f61aceb-273b-409e-b527-6b07a3a2d913","keyword":"MgO-C耐火材料","originalKeyword":"MgO-C耐火材料"},{"id":"72055e6d-97ed-4fd1-ba23-0e95f5e98ce7","keyword":"抗折强度","originalKeyword":"抗折强度"},{"id":"a15edb65-544c-46d9-9662-8d9e01d66213","keyword":"Weibull模量","originalKeyword":"Weibull模量"},{"id":"8046edba-b7cb-404d-9b26-924254ec0e2e","keyword":"显微结构","originalKeyword":"显微结构"}],"language":"zh","publisherId":"nhcl201205007","title":"MgO-C耐火材料抗折强度分布规律的研究","volume":"46","year":"2012"},{"abstractinfo":"分别以微孔富镁尖晶石(5~3和3~1 mm)和电熔镁砂(5~3和3~1 mm)为粗骨料,以<1 mm的电熔镁砂为细骨料,以镁砂粉(≤0.088 mm)、鳞片石墨粉(≤0.088 mm)、金属铝粉(≤0.074 mm)为细粉,以酚醛树脂为结合剂,制备了w(C)=6%的两种低碳MgO-C材料,经220和1 500℃(埋焦炭)热处理后,测定其显气孔率、常温耐压强度、常温抗折强度、加热永久线变化率、抗热震性和抗渣性.结果表明:1)用微孔富镁尖晶石骨料取代普通低碳MgO-C材料中的部分镁砂骨料后,经220和1 500℃热处理后试样的显气孔率均比普通低碳MgO-C试样的大,体积密度均比普通低碳MgO-C试样的小;220℃固化后试样的强度比普通低碳MgO-C试样的小,但1 500℃热处理后试样的强度比普通低碳MgO-C试样的大;1 500℃热处理后试样的加热永久线变化率比普通低碳MgO-C试样的小.2)使用微孔富镁尖晶石骨料代替电熔镁砂骨料能有效提高低碳MgO-C材料的抗热震性,但对低碳MgO-C材料的抗侵蚀性不利.","authors":[{"authorName":"彭从华","id":"e0ec5a34-77cd-4722-961b-92eb90e483f0","originalAuthorName":"彭从华"},{"authorName":"李楠","id":"fbc11f1b-20fb-4628-9e4d-7878fa2d41ad","originalAuthorName":"李楠"},{"authorName":"韩兵强","id":"8c0d3c77-c0be-4814-89a7-3dbd96d9299e","originalAuthorName":"韩兵强"}],"doi":"10.3969/j.issn.1001-1935.2009.05.005","fpage":"335","id":"0d8bd918-407f-473c-9b75-4440eb4d13fd","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":"03e6e97d-7a5b-44dc-be0b-0fb978819978","keyword":"微孔富镁尖晶石","originalKeyword":"微孔富镁尖晶石"},{"id":"a6ba88ab-5983-4f39-8c39-b2b80a340cc7","keyword":"电熔镁砂","originalKeyword":"电熔镁砂"},{"id":"dd150563-7e30-4ae6-b8ec-dfb6eb22b965","keyword":"低碳镁碳材料","originalKeyword":"低碳镁碳材料"},{"id":"c1dd6b77-915b-451c-af9b-0353b84f96a0","keyword":"抗热震性","originalKeyword":"抗热震性"},{"id":"62775831-8f5d-4e5d-bff4-21d12036bfe5","keyword":"抗渣性","originalKeyword":"抗渣性"}],"language":"zh","publisherId":"nhcl200905005","title":"微孔富镁尖晶石对低碳MgO-C材料性能的影响","volume":"43","year":"2009"},{"abstractinfo":"以碱度为 3.0和1.0的钢渣对石墨含量(w)为0、2%、4%、6%和12%的MgO-C质试样进行了回转抗渣试验,并对侵蚀后试样进行了SEM、EDAX和EPMA分析.结果表明:当石墨含量(w)≤6%时,试样在两种渣中的侵蚀深度都随石墨含量的增加而减小,而当石墨含量(w)达到12%时,其侵蚀深度又都增加;碱度1.0的渣对石墨含量(w)≤6%的MgO-C材料的侵蚀严重,而碱度3.0的渣对石墨含量(w)为12%的MgO-C材料的侵蚀严重;低碱度渣中Si、Fe对MgO致密层的熔损比高碱度渣中的严重.","authors":[{"authorName":"李林","id":"60aed66f-9fcb-461a-8bb6-0a237e4dcb03","originalAuthorName":"李林"},{"authorName":"洪彦若","id":"dc169964-bed0-4e82-a784-2c30a26e5790","originalAuthorName":"洪彦若"},{"authorName":"孙加林","id":"c9c23aa4-72f7-441b-beae-5f8bc306b5e5","originalAuthorName":"孙加林"},{"authorName":"彭小艳","id":"54c043f6-223a-415b-a0da-093df5f71db5","originalAuthorName":"彭小艳"},{"authorName":"贺智勇","id":"f2aab230-21b4-4b0c-8d9e-867b4ec2af8f","originalAuthorName":"贺智勇"},{"authorName":"于力","id":"0ae59052-bf7f-45c3-a1ba-6d0bbd85fa3f","originalAuthorName":"于力"}],"doi":"10.3969/j.issn.1001-1935.2004.05.001","fpage":"297","id":"4cf241ec-01fc-4a78-b0e1-6de01ac576c8","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":"5b3d2bde-3a57-475d-a657-15f0914823a2","keyword":"低炭镁炭质耐火材料","originalKeyword":"低炭镁炭质耐火材料"},{"id":"abe35640-e5f8-4187-88b2-defc43e87a18","keyword":"抗渣侵蚀性","originalKeyword":"抗渣侵蚀性"},{"id":"8156aa5b-7b42-4b43-b669-47da1bc43db9","keyword":"侵蚀机理","originalKeyword":"侵蚀机理"}],"language":"zh","publisherId":"nhcl200405001","title":"低炭MgO-C质耐火材料的抗熔渣侵蚀行为","volume":"38","year":"2004"}],"totalpage":7549,"totalrecord":75487}