{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"采用特级矾土、黏土为主要原料,液体磷酸盐做结合剂,制备了6种满足不同施工方式的w(Al2O3)>70%的高铝可塑料,并采用马夏值测定仪测定了可塑料的可塑性.结果表明:马夏值测定法可以用于耐火可塑料的可塑性测定,而且其检测范围更宽,可测定采用橡皮锤人工捣打或风镐机械捣打等不同施工方式的可塑料的可塑性.橡皮锤人工捣打可塑料的马夏值范围为1.36~3.74 MPa,风镐机械捣打可塑料的马夏值范围为7.1~22 MPa.","authors":[{"authorName":"曹喜营","id":"75c4caa4-cb66-4650-9067-a96802cbd298","originalAuthorName":"曹喜营"},{"authorName":"张三华","id":"43ffecdb-33e9-4587-943d-7c3cca4ceb55","originalAuthorName":"张三华"},{"authorName":"石会营","id":"74153ff2-9fb1-4c8a-ab01-11ea89d857bb","originalAuthorName":"石会营"},{"authorName":"王金相","id":"2a1842f6-d156-4294-9978-b13ab33937d2","originalAuthorName":"王金相"},{"authorName":"洪彦若","id":"1ba110b1-55eb-4bdb-9617-fa7f68da0f6e","originalAuthorName":"洪彦若"},{"authorName":"李再耕","id":"bf228091-639a-406c-979b-de66faebbf18","originalAuthorName":"李再耕"}],"doi":"10.3969/j.issn.1001-1935.2009.06.015","fpage":"456","id":"1f9ca5f2-d90c-4817-a0ea-f1443735996c","issue":"6","journal":{"abbrevTitle":"NHCL","coverImgSrc":"journal/img/cover/NHCL.jpg","id":"55","issnPpub":"1001-1935","publisherId":"NHCL","title":"耐火材料 "},"keywords":[{"id":"c6527163-0345-4f02-86c3-414f7ac5e25e","keyword":"耐火可塑料","originalKeyword":"耐火可塑料"},{"id":"17abe30e-e375-4791-90c4-3902889717d3","keyword":"马夏值","originalKeyword":"马夏值"},{"id":"e85deede-fb42-4f63-94ec-fc04241724db","keyword":"可塑性","originalKeyword":"可塑性"},{"id":"6b06311f-183d-4f12-956d-3348733d141c","keyword":"施工方法","originalKeyword":"施工方法"}],"language":"zh","publisherId":"nhcl200906015","title":"耐火可塑料马夏值的测定","volume":"43","year":"2009"},{"abstractinfo":"本文通过XRD物相分析和SEM微观形貌分析研究了不同结合剂对矾土基可塑料物理性能的影响,探明了其结合机理.结果表明:矾土骨料最佳颗粒级配为:3~1 mm/≤1 mm/≤0.074 mm=47/18/25,其中软质粘土占骨料总质量的10%;其中以六偏磷酸钠和偏硅酸钠为结合剂的试样常温性能优于其他试样,试样在添加剂中引入了Na+和Ca2,使得在试样在烧结中抑制了莫来石的形成,同时产生低熔物,提高烧结致密性,降低了显气孔率,导致其常温物理性能较好,但高温性能较差.","authors":[{"authorName":"白晨","id":"086ab9b2-182d-4257-94ce-2f5a22fafc67","originalAuthorName":"白晨"},{"authorName":"祝洪喜","id":"2d5dd86d-c287-4c97-b718-ee303fdeca5c","originalAuthorName":"祝洪喜"},{"authorName":"邓承继","id":"4464a6e5-cc25-4a24-89a7-684225317b0f","originalAuthorName":"邓承继"},{"authorName":"杨罗成","id":"ec8bc260-a581-422d-8417-a946f10d8d7f","originalAuthorName":"杨罗成"},{"authorName":"丁军","id":"e9414c85-1bbe-472d-8b42-f2a0c7ce44fd","originalAuthorName":"丁军"}],"doi":"","fpage":"221","id":"a5e6cfd2-8126-4ad5-aa97-4d5a06917979","issue":"1","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"06c6ca8f-e843-43a9-a462-57da13cd2b91","keyword":"耐火可塑料","originalKeyword":"耐火可塑料"},{"id":"1deddf92-b003-4a75-a5c9-2ce6adc7a51d","keyword":"结合剂","originalKeyword":"结合剂"},{"id":"ae1ede96-76d5-4aa6-a22f-ec8fd3db8905","keyword":"烧结","originalKeyword":"烧结"},{"id":"d3770b2a-3c0a-42fb-a0a3-2c47dbb41df1","keyword":"性能","originalKeyword":"性能"}],"language":"zh","publisherId":"gsytb201601039","title":"结合剂对高铝矾土可塑料性能的影响","volume":"35","year":"2016"},{"abstractinfo":"本文介绍了不定形耐火材料中的一种-可塑料的性能,并根据自己的研究成果以及近年来有关可塑料新产品的制备、应用等方面的最新研究,系统地论述了不同种类的可塑料的性能以及研究进展.同时,针对可塑料的施工提出了一些建议.在此基础上,展望了可塑料今后的发展趋势.","authors":[{"authorName":"张巍","id":"f1d648f3-2180-4c8d-af81-c28bfc36c56c","originalAuthorName":"张巍"}],"doi":"","fpage":"316","id":"abf48b6c-32dc-4e0e-995d-a8f9bbfb4b9d","issue":"2","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"daca949b-57a8-42eb-9aef-00dae1b667dd","keyword":"可塑料","originalKeyword":"可塑料"},{"id":"63136fe6-d616-4f9e-8306-9deea41250c0","keyword":"不定形耐火材料","originalKeyword":"不定形耐火材料"},{"id":"153d979e-aab3-44fa-9de0-43f10492c57b","keyword":"施工","originalKeyword":"施工"}],"language":"zh","publisherId":"gsytb201202018","title":"不定形耐火材料之可塑料的研究进展","volume":"31","year":"2012"},{"abstractinfo":"以高铝矾土、二氧化硅微粉和氧化铝微粉为原料,以磷酸二氢铝和磷酸为结合剂,制备了用于CFB锅炉的高铝质可塑料,重点研究镁砂细粉用量对高铝质可塑料性能的影响.按照不定形耐火材料检测标准对热处理后耐火可塑料的常温力学性能、致密性及耐磨性能进行检测,通过XRD和SEM分析手段对热处理后试样的物相组成和微观结构进行表征.结果表明:镁砂对可塑料起到促凝和促烧结作用,随着镁砂加入量增大,促凝时间缩短,经110℃热处理后试样常温强度逐渐增大,经1100℃热处理后试样常温强度呈先增大后减小趋势.当镁砂加入量为5%,1100℃热处理后试样常温强度和结构致密性可处于最高值,耐磨性有所降低,试样矿物相组成中包括刚玉、莫来石和堇青石相.","authors":[{"authorName":"李美葶","id":"c88190c2-cfff-4318-8fcd-f9ca8e4b027a","originalAuthorName":"李美葶"},{"authorName":"张国栋","id":"bea7c0bb-5c03-4b73-a3a1-d9eb7cb9df61","originalAuthorName":"张国栋"},{"authorName":"罗旭东","id":"1b67b22c-00d2-4f3b-acad-20827f45a350","originalAuthorName":"罗旭东"},{"authorName":"武永兴","id":"9b9af55f-3015-4d3b-b008-7aaf82c48987","originalAuthorName":"武永兴"}],"doi":"","fpage":"788","id":"209387d9-4fdf-4298-9425-e3ebbb307b8a","issue":"3","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"e218918f-0975-46bb-b1db-585788243332","keyword":"镁砂","originalKeyword":"镁砂"},{"id":"32135022-d0bf-4bda-aeae-d99d948412cd","keyword":"高铝质可塑料","originalKeyword":"高铝质可塑料"},{"id":"ee2d6011-9dcf-4b55-88c6-1dbf915c0e97","keyword":"CFB锅炉","originalKeyword":"CFB锅炉"},{"id":"b14c8879-e0fa-4f33-bfcc-a0842b6d55bf","keyword":"促凝时间","originalKeyword":"促凝时间"}],"language":"zh","publisherId":"gsytb201503035","title":"镁砂对高铝质可塑料性能影响","volume":"34","year":"2015"},{"abstractinfo":"采用 w(Al2 O3)≥87.5%、粒度为5~3、3~1、≤1、<0.074 mm 的特级矾土,w(Al2 O3)≥99.4%、粒度为5μm 的烧结氧化铝微粉,w(Al2 O3)≥20%的黏土粉,改性淀粉以及添加剂配成可塑料。研究了改性淀粉加入量(w)0、1%、1.5%、2%、2.5%时对可塑料物理性能的影响。结果表明:1)采用1.5%(w)的改性淀粉就可以替代5%(w)的黏土,增强可塑料的保湿性和可塑性,延长了其保存期;2)使用改性淀粉有助于减少可塑料液体结合剂的加入量,提高材料烘干和热处理后的常温强度。","authors":[{"authorName":"肖家志","id":"43d4b42c-9279-40b5-86b8-076bce87c7a3","originalAuthorName":"肖家志"},{"authorName":"梁亚丽","id":"913c926f-4d46-49de-9626-cf00f6b7e6dd","originalAuthorName":"梁亚丽"},{"authorName":"张军","id":"2a304ad7-4cba-4979-9849-bae380986906","originalAuthorName":"张军"},{"authorName":"禄向阳","id":"99efa744-0b61-49c6-b374-a5b5ea6f05e9","originalAuthorName":"禄向阳"}],"doi":"10.3969/j.issn.1001-1935.2015.05.018","fpage":"391","id":"1d3a8452-51a6-4692-bdc9-2b94b2fba09b","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":"24c1586a-f816-463b-a260-00ebeb06ace1","keyword":"改性淀粉","originalKeyword":"改性淀粉"},{"id":"992d6616-0fa9-4c0e-b90d-f5eb7159cf0d","keyword":"可塑料","originalKeyword":"可塑料"},{"id":"e4739113-adc8-4867-b976-35e5746958df","keyword":"保存期","originalKeyword":"保存期"},{"id":"009793b8-6753-498b-80a0-6fa97833ee62","keyword":"物理性能","originalKeyword":"物理性能"}],"language":"zh","publisherId":"nhcl201505018","title":"改性淀粉加入量对可塑料性能的影响","volume":"","year":"2015"},{"abstractinfo":"以电熔莫来石(体积密度2.90 g·cm-3)、硅灰、红柱石(灼减≤1.5%)、广西白泥、SiC、α-Al2O3微粉、棕刚玉粉、六偏磷酸钠为原料,配成脱硫枪热修补可塑料.固定电熔莫来石加入量、SiC、硅灰和α-Al2O3微粉的加入量,分别以5%、10%和15%的广西白泥,或3%、6%和9%的红柱石粉.或1%、3%、5%的六偏磷酸钠取代等量的棕刚玉粉,研究了广西白泥、红柱石、六偏磷酸钠以及草酸加入量(外加,分别为1%、2%、3%)分别对脱硫枪热修补可塑料的可塑性、线变化率、耐压强度以及可塑料保存期的影响.并结合试验结果优化配方进行了工业试验,结果表明:(1)结合剂六偏磷酸钠的用量为3%时最佳;(2)可以通过改变保存剂草酸的加入量来改善热修补可塑料的保存期限;(3)通过热修补可以显著提高Ⅲ部脱硫枪的使用寿命,热修补可塑料同样可用于修补Ⅰ、Ⅱ部脱硫枪的裂纹,但修补效果不如Ⅲ部脱硫枪的.","authors":[{"authorName":"王洪芳","id":"f7d6359f-43f7-462a-8910-79d363a234d3","originalAuthorName":"王洪芳"},{"authorName":"段大福","id":"dc01ebd4-4d50-45f1-b570-aba1c02d075a","originalAuthorName":"段大福"}],"doi":"10.3969/j.issn.1001-1935.2008.04.012","fpage":"282","id":"070e5c42-e7b3-4fc4-9be3-f24539389898","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":"9200e069-aabf-46b8-8568-4f2dead892c3","keyword":"脱硫枪","originalKeyword":"脱硫枪"},{"id":"4092c1d5-f9ee-42bc-af1b-33761d4f894d","keyword":"热修补","originalKeyword":"热修补"},{"id":"ef482541-e745-4b31-9543-1a31c9e49c05","keyword":"可塑料","originalKeyword":"可塑料"}],"language":"zh","publisherId":"nhcl200804012","title":"攀钢脱硫枪热修补可塑料的研制","volume":"42","year":"2008"},{"abstractinfo":"为了提高可塑料的抗冻结能力,以粒度为6~3、3~1、≤1 mm的焦宝石(w(Al2O3)>45%,w(SiO2)<52%)和粒度≤45μm的黏土(w(Al2O3)>26%,w(SiO2)<65%)为原料,加入硫酸铝溶液、水和乙二醇防冻液制备出防冻型黏土质可塑料.将试样放入零下15℃的试验箱中冷冻,在室温下放置至室温,再经110℃干燥和1 000℃热处理后,分别测试试样的线变化率、抗折强度、耐压强度和体积密度,并与常温20℃下放置的试样的各项性能加以比较.结果表明:试样经过110℃和1 000℃热处理后,普通可塑料试样在零下15℃冻结后的强度比正常未冻结试样的下降约20%,而防冻型可塑料与正常试样相比,在强度方面几乎没有改变.","authors":[{"authorName":"戴文勇","id":"9e12d6e4-866f-4262-acca-a997cb114e8a","originalAuthorName":"戴文勇"},{"authorName":"小宫山勇","id":"3d4003e7-2243-409a-b4a4-0a3710e0bbf4","originalAuthorName":"小宫山勇"},{"authorName":"张巍","id":"ee5c58e2-833e-4a26-a794-47ca26e58955","originalAuthorName":"张巍"},{"authorName":"么荫智","id":"266e50bd-1b96-448e-ae70-7d83a382caad","originalAuthorName":"么荫智"}],"doi":"10.3969/j.issn.1001-1935.2009.01.017","fpage":"62","id":"1a35f95b-ed0a-4c05-8b1c-f07f4991e90f","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":"b8159ee6-e510-43b4-98c5-0e0b8633cb99","keyword":"防冻型可塑料","originalKeyword":"防冻型可塑料"},{"id":"434275bf-aa85-4440-9c99-e83d1be6a903","keyword":"冻结","originalKeyword":"冻结"},{"id":"0be4e6b3-5133-4e09-9826-735afb89f74d","keyword":"可塑性指数","originalKeyword":"可塑性指数"}],"language":"zh","publisherId":"nhcl200901017","title":"防冻型黏土质可塑料的研制","volume":"43","year":"2009"},{"abstractinfo":"为了延长高铝可塑料的保质期,采用粒度为5~3、3~1、≤1、≤0.045 mm的特级矾土、≤2μm的黏土为主要原料,磷酸为结合剂,制备高铝可塑料,并通过添加聚磷酸盐AP、过磷酸盐P2及羟基羧酸盐TP等不同保存剂来提高可塑料的保存期.通过测量可塑料马夏值的变化来衡量可塑料的塑性变化,同时研究了保存剂对可塑料物理性能的影响.结果表明:3种保存剂的加入均能提高可塑料的保存期,并对可塑料其他性能影响较小.其中,加入羟基羧酸盐TP作为保存剂的效果最好,可塑料保存6个月后依然保持较好的塑性.","authors":[{"authorName":"张效峰","id":"44f50c59-6d78-4b41-afae-3983c910c884","originalAuthorName":"张效峰"},{"authorName":"张军","id":"6cc71d30-a424-474b-a5a3-fb16ea5ec721","originalAuthorName":"张军"},{"authorName":"韦祎","id":"9b96ac0a-9562-4416-86ba-afd91ef0125d","originalAuthorName":"韦祎"},{"authorName":"禄向阳","id":"e5d9ee5d-0e90-403e-95a8-2e29ecd5ff8c","originalAuthorName":"禄向阳"},{"authorName":"秦红彬","id":"07ede308-7162-4cd9-831f-5a61abf9514b","originalAuthorName":"秦红彬"},{"authorName":"张三华","id":"93d76daf-d785-4075-9c15-c76d151049f4","originalAuthorName":"张三华"}],"doi":"10.3969/j.issn.1001-1935.2016.04.017","fpage":"304","id":"0377cb5d-938f-45df-a242-5dd83bc14ffe","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":"3993070c-efd8-48c1-aed1-69ad3e47da5d","keyword":"高铝可塑料","originalKeyword":"高铝可塑料"},{"id":"4b9c581d-7b02-4226-9d5b-633bc81fd68c","keyword":"保存剂","originalKeyword":"保存剂"},{"id":"b4f9b2e7-4381-4b95-a1d2-98ebb2d94517","keyword":"马夏值","originalKeyword":"马夏值"},{"id":"66a25416-0b4b-4456-b083-c7bd37efc1c9","keyword":"保存期","originalKeyword":"保存期"}],"language":"zh","publisherId":"nhcl201604017","title":"三种保存剂对磷酸结合高铝可塑料性能的影响","volume":"50","year":"2016"},{"abstractinfo":"以高铝矾土、二氧化硅微粉和氧化铝微粉为原料,以磷酸二氢铝和磷酸为结合剂,制备了用于 CFB 锅炉的高铝质耐磨可塑料。重点研究市售60、65、70和75四种铝酸钙水泥对烘干后及1100℃热处理后高铝质耐磨可塑料体积密度、常温力学性能、烧后线变化率、耐磨性及促凝性的影响,并通过 XRD 和 SEM对热处理后试样物相组成和断面显微结构进行了分析。结果表明:随着铝酸钙水泥中氧化铝含量的增大以及氧化钙含量的减小,烘干和热处理后高铝质耐磨可塑料体积密度、常温力学性能和耐磨性会逐渐降低,并且氧化钙含量的减小还会削弱铝酸钙水泥对高铝质耐磨可塑料的促凝作用。热处理后高铝质耐磨可塑料物相组成为刚玉相和莫来石相,促凝剂铝酸盐水泥中氧化铝含量增大,会加强可塑料中刚玉相的结晶特征。","authors":[{"authorName":"罗旭东","id":"79a14840-e389-4a51-9198-784e4aa840a8","originalAuthorName":"罗旭东"},{"authorName":"占华生","id":"040f8f6b-3b2f-4fac-b4e0-a8523bffa030","originalAuthorName":"占华生"},{"authorName":"李燕京","id":"b9215af4-1ea9-46e7-ab45-9de96ba38cc7","originalAuthorName":"李燕京"},{"authorName":"谢志鹏","id":"8e5bcb48-9313-4e93-bb70-f1ec1abd92cb","originalAuthorName":"谢志鹏"},{"authorName":"武永兴","id":"e5a282b0-f039-4ed3-843c-5ee51f03f88d","originalAuthorName":"武永兴"}],"doi":"10.3969/j.issn.1001-1935.2015.04.004","fpage":"255","id":"2b019678-9630-4816-ac88-a0b0c82ec701","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":"46b30e5b-b54d-4c5a-b133-4a3241d36bbd","keyword":"铝酸盐水泥","originalKeyword":"铝酸盐水泥"},{"id":"74aa7c1c-4ac8-4b35-b0c9-9e39d795a930","keyword":"高铝质耐磨可塑料","originalKeyword":"高铝质耐磨可塑料"},{"id":"9c9bcc53-3fca-4a96-a1dc-f660636443d8","keyword":"耐磨性","originalKeyword":"耐磨性"},{"id":"d9ebbecc-ad5a-45ff-9a79-e542aca2b05b","keyword":"促凝性","originalKeyword":"促凝性"}],"language":"zh","publisherId":"nhcl201504004","title":"水泥种类对高铝质耐磨可塑料性能的影响","volume":"","year":"2015"},{"abstractinfo":"以铝矾土颗粒、细粉及黏土为主要原料,研究了自来水、饱和硫酸铝溶液、饱和硫酸铝溶液+磷酸二氢铝溶液3种结合剂对高铝可塑料性能的影响.结果表明:以硫酸铝为结合剂的保质期最长,以磷酸二氢铝+硫酸铝为结合剂的保质期最短;分别以硫酸铝和硫酸铝+磷酸二氢铝为结合剂的试样烘干后耐压强度高于以水为结合剂的;3种结合剂结合试样的体积密度和荷重软化温度(变形量分别为0.5%、1%、2%)相差不大.","authors":[{"authorName":"王京京","id":"470b040e-2889-4d73-81f9-299c99ffbace","originalAuthorName":"王京京"},{"authorName":"王成","id":"bd87d1be-7179-4e09-bc70-be13cf51c1b8","originalAuthorName":"王成"},{"authorName":"潘磊","id":"16998870-0eee-4853-9186-2456d06a0109","originalAuthorName":"潘磊"}],"doi":"10.3969/j.issn.1001-1935.2013.01.012","fpage":"46","id":"13e7ad81-eeaa-4502-bbc8-f0b0bd6b8456","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":"22b2e3ad-a3fe-49e0-b4c6-ee65948de115","keyword":"高铝可塑料","originalKeyword":"高铝可塑料"},{"id":"16e5e792-93eb-4cfe-a35e-5d520a3a6361","keyword":"结合剂","originalKeyword":"结合剂"},{"id":"0623f12b-f9d0-47a9-833f-0c10dc777987","keyword":"保质期","originalKeyword":"保质期"},{"id":"84f36733-1ced-481f-8c60-623fb400e92c","keyword":"荷重软化温度","originalKeyword":"荷重软化温度"}],"language":"zh","publisherId":"nhcl201301012","title":"不同结合剂对高铝可塑料性能的影响","volume":"47","year":"2013"}],"totalpage":267,"totalrecord":2667}