{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"以页岩为主要原料,通过不同热处理过程制备了微晶玻璃.利用XRD和SEM测试手段,分析了核化时间和晶化时间对微晶玻璃晶相特征的影响.结果表明,晶化时间的增加使微晶玻璃主晶相钙长石含量降低,次晶相钙硅石含量逐渐增加;核化时间的增加有利于球状晶粒尺寸增大,晶化时间的延长使晶粒聚集成团,排列紧密.微晶玻璃具有较高的抗压强度和良好的耐腐蚀性,可作为天然石料的替代品和装饰材料.","authors":[{"authorName":"栾敬德","id":"35faa361-469f-4887-89c2-14a522930270","originalAuthorName":"栾敬德"},{"authorName":"李爱民","id":"d3dd99da-4fbf-4a13-bba4-547ba0ab4ddc","originalAuthorName":"李爱民"},{"authorName":"崔晓波","id":"faa950e4-3e2c-4465-af53-0e36e691e840","originalAuthorName":"崔晓波"},{"authorName":"苏瞳","id":"702efc76-5440-416f-8aa3-f69af84b7834","originalAuthorName":"苏瞳"}],"doi":"","fpage":"1","id":"612cd15b-b588-4002-8d41-417703c0dfae","issue":"7","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":"7f4b4f2d-77e3-405d-88fd-3a89fe510945","keyword":"页岩","originalKeyword":"页岩飞灰"},{"id":"292575f6-370e-4d2f-b910-664ef99f0790","keyword":"微晶玻璃","originalKeyword":"微晶玻璃"},{"id":"b6b0bf30-b978-4ec6-82ac-1e798a286574","keyword":"核化","originalKeyword":"核化"},{"id":"19a82744-eeb4-416e-9e61-be837d854e82","keyword":"晶化","originalKeyword":"晶化"}],"language":"zh","publisherId":"jsrclxb201007001","title":"核化和晶化时间对页岩微晶玻璃性能的影响","volume":"31","year":"2010"},{"abstractinfo":"油页岩经HNO3和不同浓度NaOH溶液改性处理制备了改性油页岩吸附剂,比较了各种改性油页岩吸附剂对Cu2+的吸附性能,分别讨论了吸附时间、Cu2+浓度和溶液pH值对吸附性能的影响.结果表明,分别经50%HNO3、20%NaOH溶液处理制备的改性油页岩吸附剂对Cu2+具有较好的吸附性能,且以化学吸附作用方式为主.该改性油页岩吸附剂对Cu2+的吸附符合Freundlich等温吸附方程.","authors":[{"authorName":"李勇","id":"4652457c-c537-4d80-a962-f96c82eda536","originalAuthorName":"李勇"},{"authorName":"薛向欣","id":"801316ff-af94-445a-bc71-a3b67a98b9d7","originalAuthorName":"薛向欣"},{"authorName":"冯宗玉","id":"604986c8-bbb1-4a40-a3c0-128a173b0fa3","originalAuthorName":"冯宗玉"}],"doi":"10.3969/j.issn.1671-6620.2007.04.014","fpage":"302","id":"9ba995f8-663e-416f-abb7-b36f7c68e1b6","issue":"4","journal":{"abbrevTitle":"CLYYJXB","coverImgSrc":"journal/img/cover/CLYYJXB.jpg","id":"17","issnPpub":"1671-6620","publisherId":"CLYYJXB","title":"材料与冶金学报"},"keywords":[{"id":"3e378402-3501-4107-b06d-987204f44113","keyword":"改性油页岩","originalKeyword":"改性油页岩灰"},{"id":"36142b4c-5715-4764-8572-0721d39595ec","keyword":"吸附","originalKeyword":"吸附"},{"id":"b2bbc38c-468c-4c29-94b9-bf273336797e","keyword":"铜离子","originalKeyword":"铜离子"}],"language":"zh","publisherId":"clyyjxb200704014","title":"改性油页岩吸附Cu2+的研究","volume":"6","year":"2007"},{"abstractinfo":"通过试验研究确定大庆油页岩符合火山灰质混合材要求,能与熟料掺混生产水泥.配制了不同油页岩掺混量的水泥样品,按照国标进行强度试验,并采用X-射线衍射仪分析了28 d胶砂试块的物相组成.结果表明:随着油页岩掺量的增加,水泥样品胶砂强度整体呈下降趋势,且前期下降幅度大,后期小;高掺混量时熟料中的C3A矿物含量不足,试样检测出钙矾石;油页岩掺量为5~10%,水泥样品强度仍能达到与熟料的相同的强度等级;掺量为15~20%,其强度亦接近熟料的强度等级;掺量在20%以上时,强度下降显著.","authors":[{"authorName":"王盘成","id":"ef2d256f-df68-4410-8438-90bf071c1f01","originalAuthorName":"王盘成"},{"authorName":"吴国光","id":"8b2f60fe-4887-4f48-b34c-7db9a183cd53","originalAuthorName":"吴国光"},{"authorName":"赵娜","id":"4e20eb10-06d6-46c7-8b3e-20b6162c8335","originalAuthorName":"赵娜"},{"authorName":"苗真勇","id":"c854ce9e-db51-4af2-8ec3-aefabf3f4da8","originalAuthorName":"苗真勇"},{"authorName":"李萍","id":"8470c83b-8220-4e86-85cd-72c7e1fb5d00","originalAuthorName":"李萍"},{"authorName":"孟献梁","id":"fd410e23-1735-4018-8943-5ea0a46c9654","originalAuthorName":"孟献梁"},{"authorName":"王志华","id":"c546af1b-d931-4ee8-80cf-c2d9c7951a3b","originalAuthorName":"王志华"}],"doi":"","fpage":"580","id":"6efed2f5-d32d-4ff9-8119-167c15dce656","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":"c9ec81c2-7a3f-4f2f-9981-922fdb53a4a0","keyword":"油页岩","originalKeyword":"油页岩灰"},{"id":"d14bc641-0ccd-4a69-b22a-ef55c8c45e71","keyword":"火山灰质混合材","originalKeyword":"火山灰质混合材"},{"id":"dd330c7a-0ced-41f7-931f-11ed76bc48b2","keyword":"流动度","originalKeyword":"流动度"},{"id":"f3c5389b-4c77-4cef-96fe-c84d859ea051","keyword":"水灰比","originalKeyword":"水灰比"},{"id":"d3fd1719-ef0b-47d7-a177-51fc595c117a","keyword":"水泥强度","originalKeyword":"水泥强度"}],"language":"zh","publisherId":"gsytb200903036","title":"油页岩作水泥混合材的研究","volume":"28","year":"2009"},{"abstractinfo":"以油页岩为主要原料,通过烧结法制备陶粒,用其作为吸附剂,使油页岩资源得到综合利用.通过吸附苯酚实验,确定了陶粒中油页岩的最佳含量为90%,最佳烧结温度为1 150 ℃;苯酚的吸附率随着陶粒用量的增加而增大,对25.0 mL 0.1g/L的苯酚溶液,陶粒用量为2.0 g时,具有较好的吸附率;随着吸附时间的增加,苯酚的吸附率也逐渐增加,150 min达到吸附平衡;当苯酚初始质量浓度大于0.1 g/L时,陶粒对苯酚的吸附率达到70%左右,具有较好的应用价值.","authors":[{"authorName":"冯宗玉","id":"0dda62b2-2234-4b93-83dd-571a18348b4f","originalAuthorName":"冯宗玉"},{"authorName":"薛向欣","id":"906c1655-29e9-4b1a-ba2e-cdf790ff3f34","originalAuthorName":"薛向欣"},{"authorName":"李勇","id":"585033cf-ad3f-4c57-a5cb-f76bbe14eb22","originalAuthorName":"李勇"}],"doi":"10.3969/j.issn.1671-6620.2007.03.014","fpage":"230","id":"669d3e53-67a9-4a41-9811-ef322cc1cf4d","issue":"3","journal":{"abbrevTitle":"CLYYJXB","coverImgSrc":"journal/img/cover/CLYYJXB.jpg","id":"17","issnPpub":"1671-6620","publisherId":"CLYYJXB","title":"材料与冶金学报"},"keywords":[{"id":"8d97a94a-35ed-4ec8-8484-8cef45ff2f05","keyword":"油页岩","originalKeyword":"油页岩灰"},{"id":"ee499876-9ddf-4b34-a243-41ba34211437","keyword":"陶粒","originalKeyword":"陶粒"},{"id":"2d639e68-f81b-4c52-96a1-67d2aa4ff75b","keyword":"吸附剂","originalKeyword":"吸附剂"},{"id":"3ac66534-3f9c-4c00-b1e7-70e40c4c89ba","keyword":"苯酚","originalKeyword":"苯酚"}],"language":"zh","publisherId":"clyyjxb200703014","title":"油页岩陶粒吸附苯酚的实验研究","volume":"6","year":"2007"},{"abstractinfo":"为实现垃圾焚烧过程中砷的释放控制,本文采集了六个地区两种炉型垃圾焚烧电厂的,通过分析中砷的赋存形态,阐释了垃圾焚烧过程中砷的迁移转化机理.结果表明,中砷总量存在一定的地域性差异,且炉排炉中砷含量高于流化床.中的As(Ⅲ)极少(0.34%~9.56%),大部分砷在高温焚烧过程中与Ca、Fe、Al等元素化合物发生交互反应以As(V)存在于飞中,此外,少量砷被硅铝酸盐固化在基质中.","authors":[{"authorName":"徐章","id":"0595f3fe-87b9-4d15-a456-b61cf6fd91e7","originalAuthorName":"徐章"},{"authorName":"胡红云","id":"a3fd55c5-64b2-49b1-9fb8-797915ad4d85","originalAuthorName":"胡红云"},{"authorName":"陈敦奎","id":"ef203e5a-f2fe-4f40-8600-16b8c272a616","originalAuthorName":"陈敦奎"},{"authorName":"刘欢","id":"03e3de92-a874-49ad-971c-50560ed1078f","originalAuthorName":"刘欢"},{"authorName":"姚洪","id":"d9f8fedf-2ee9-4121-bf4b-b67caccf6365","originalAuthorName":"姚洪"}],"doi":"","fpage":"2071","id":"90a14d35-56af-4fd6-92ed-29ea22d4c127","issue":"9","journal":{"abbrevTitle":"GCRWLXB","coverImgSrc":"journal/img/cover/GCRWLXB.jpg","id":"32","issnPpub":"0253-231X","publisherId":"GCRWLXB","title":"工程热物理学报 "},"keywords":[{"id":"70164603-2071-496b-8abc-d14b246cd8ee","keyword":"垃圾焚烧","originalKeyword":"垃圾焚烧"},{"id":"7bba03d7-c9d0-4837-8651-33ddc4b0c1c2","keyword":"","originalKeyword":"飞灰"},{"id":"4c0df962-01fd-446a-948f-ab87b0392c86","keyword":"砷","originalKeyword":"砷"},{"id":"f1b98ddd-34e0-4b05-80f7-8b54da5768e6","keyword":"赋存形态","originalKeyword":"赋存形态"}],"language":"zh","publisherId":"gcrwlxb201509047","title":"垃圾焚烧中砷的赋存形态研究","volume":"36","year":"2015"},{"abstractinfo":"高压放电对表面特性会产生影响从而改变颗粒的荷电特性。使用高压窄脉冲电源大幅提高静电除尘器的放电电压,通过对不同电压放电前后表面特性进行分析,得到其影响规律。随着放电电压的升高,表面受到越来越严重的破坏,从开始相对光滑完整的表面结构逐渐转变为具有蜂窝状的新结构。放电电压越高,蜂窝的孔密度越高,孔径越小。复杂的表而结构使得可以得到更高的荷电量,从而提高除尘效率。","authors":[{"authorName":"王鹏","id":"c34903a8-4f30-4906-a3bb-26aa66d16028","originalAuthorName":"王鹏"},{"authorName":"骆仲泱","id":"e3048505-bc2a-46ce-b30b-7fdad6e45c5f","originalAuthorName":"骆仲泱"},{"authorName":"徐","id":"61b3f96a-cda2-4768-92d3-1f1ee2581164","originalAuthorName":"徐飞"}],"doi":"","fpage":"1797","id":"dd57524a-78ce-4cd2-bbad-21d0a4b4a7d4","issue":"10","journal":{"abbrevTitle":"GCRWLXB","coverImgSrc":"journal/img/cover/GCRWLXB.jpg","id":"32","issnPpub":"0253-231X","publisherId":"GCRWLXB","title":"工程热物理学报 "},"keywords":[{"id":"e8ec2cae-7973-4803-90dc-48f570c70a98","keyword":"高压放电","originalKeyword":"高压放电"},{"id":"59d3c73b-934f-4514-9551-a1ac72db034d","keyword":"可吸入颗粒物","originalKeyword":"可吸入颗粒物"},{"id":"1a9bd139-e811-44f8-9037-0194fef3f2b5","keyword":"","originalKeyword":"飞灰"},{"id":"f3842a20-1fc1-41aa-8b31-b69c8fda1817","keyword":"表面特性","originalKeyword":"表面特性"},{"id":"baa43ca6-ee2f-446c-81ae-8d201a4eea8b","keyword":"静电除尘器","originalKeyword":"静电除尘器"}],"language":"zh","publisherId":"gcrwlxb201110044","title":"高压放电对表面特性的影响","volume":"32","year":"2011"},{"abstractinfo":"利用水泥胶砂强度比和火山活性试验法,对经750~ 900℃、保温时间60~ 150 min煅烧处理的页岩火山活性进行了评定;结果表明:经煅烧处理后的页岩均具有活性,活性最高的是经过850℃,120 min煅烧处理的页岩,火山活性指数达到99.6%;而过高的煅烧温度和时间(温度高于900℃时间大于90 min)会导致活性急剧下降.通过XRD测试手段,对页岩获得火山活性的机理进行了分析,分析发现当煅烧温度高于750℃后,页岩中的粘土矿物高岭石衍射峰消失,碳酸盐矿物白云石衍射峰消失,出现碳酸钙和方镁石衍射峰,温度为850℃后碳酸钙衍射峰消失,随着温度提高伊利石衍射峰变弱,而烧页岩获得较高活性正是源于页岩中一些矿物的脱水和分解.","authors":[{"authorName":"元敬顺","id":"ddf6624c-2788-4344-a50b-4470e873c46c","originalAuthorName":"元敬顺"},{"authorName":"孙婧","id":"ce0fedfe-e9cb-48a7-ae7b-d59271d22c92","originalAuthorName":"孙婧"},{"authorName":"岳丽娇","id":"8237b27f-b701-409c-aa71-2d4441dc5a1e","originalAuthorName":"岳丽娇"},{"authorName":"闫杰","id":"6a77a85f-6200-4ae5-852b-dfd71f281685","originalAuthorName":"闫杰"}],"doi":"","fpage":"476","id":"dd4e757a-108a-4177-ae0c-629bb4a380f5","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":"877e33c3-093b-4e36-b86b-6d9612bd6ef3","keyword":"烧页岩","originalKeyword":"烧页岩"},{"id":"e916ed77-69c8-49ec-99ce-f1b3a1243bc5","keyword":"抗压强度比","originalKeyword":"抗压强度比"},{"id":"6f3e03c7-f853-47ec-a482-83e925c9e89a","keyword":"强度对比试验","originalKeyword":"强度对比试验"},{"id":"b7d13fb4-2722-471f-aee2-8a6c76905567","keyword":"火山性试验","originalKeyword":"火山灰性试验"},{"id":"9d7f7333-3b07-4a14-a810-c37eb3a303aa","keyword":"活性机理","originalKeyword":"活性机理"}],"language":"zh","publisherId":"gsytb201303024","title":"热激发张家口尚义页岩的火山活性研究","volume":"32","year":"2013"},{"abstractinfo":"研制了烟道式含碳量在线测量系统,实验研究了微波功率衰减量和含碳量、浓度的变化关系,进行了工业应用研究.结果表明,测量系统克服了传统单点采样型微波测试方法存在的采样缺乏代表性、样品管堵、附加设备复杂等缺点,测量精度较高,可靠性好,可以用来电站锅炉在线监测含碳量.","authors":[{"authorName":"李强","id":"e3ec9ebc-ab22-4846-a4e9-a2612c78c881","originalAuthorName":"李强"},{"authorName":"宣益民","id":"d75b631b-cd7e-4630-8cc0-9103427c9c08","originalAuthorName":"宣益民"},{"authorName":"冯长青","id":"a79dfb33-6e46-499a-aa56-0344d257fe34","originalAuthorName":"冯长青"},{"authorName":"谢仁宏","id":"945ccca4-abb0-49ab-8bf6-6535436fc1ff","originalAuthorName":"谢仁宏"}],"doi":"","fpage":"523","id":"94acf126-ac0e-4881-a223-bb1479800310","issue":"3","journal":{"abbrevTitle":"GCRWLXB","coverImgSrc":"journal/img/cover/GCRWLXB.jpg","id":"32","issnPpub":"0253-231X","publisherId":"GCRWLXB","title":"工程热物理学报 "},"keywords":[{"id":"565da460-fad8-4022-85ed-54cf769123f3","keyword":"含碳量","originalKeyword":"飞灰含碳量"},{"id":"fc683892-01fc-4139-8506-ac4d55b69923","keyword":"烟道式","originalKeyword":"烟道式"},{"id":"060e993c-768e-4fc0-b852-ab161a15b81c","keyword":"电站锅炉","originalKeyword":"电站锅炉"},{"id":"337c32dc-6362-422e-8a1d-d55dd063c0ca","keyword":"在线测量","originalKeyword":"在线测量"}],"language":"zh","publisherId":"gcrwlxb200303048","title":"MCE-1型烟道式含碳量在线测量系统的研制","volume":"24","year":"2003"},{"abstractinfo":"本文分析了焚烧的主要化学组成,对土聚物固化城市垃圾焚烧和水泥固化的效果进行了实验研究和比较,探讨了土壤聚合物固化垃圾焚烧的机理.结果表明,焚烧主要包括Ca、Cl、Si、Al、K、S、Na等,重金属包括Zn、Pb、Cu、Cd和Cr等.在相同的条件下,土聚物固化后固化体的抗压强度明显高于水泥固化体,且表现出早期抗压强度高的特点,固化体重金属的浸出毒性远低于国家有关浸出毒性标准.","authors":[{"authorName":"金漫彤","id":"1b045124-be0c-40a1-939a-635d60e11bd0","originalAuthorName":"金漫彤"},{"authorName":"董海丽","id":"bd093f35-4f86-402f-8dc9-509155105f9b","originalAuthorName":"董海丽"},{"authorName":"楼敏晓","id":"595ae061-ee61-45be-9373-5fda341ff214","originalAuthorName":"楼敏晓"},{"authorName":"王连军","id":"cb887d24-24a2-4f74-bd69-02fc26ecb0df","originalAuthorName":"王连军"}],"doi":"","fpage":"904","id":"1faa5354-4264-4c08-8a5e-39b3339ec6a1","issue":"5","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"78df6733-93a3-4b3d-933c-fdb4885ace08","keyword":"土壤聚合物","originalKeyword":"土壤聚合物"},{"id":"44dc86ae-0b38-46ca-9364-83b7ec41dd8f","keyword":"水泥","originalKeyword":"水泥"},{"id":"f69fa14c-c792-414b-9f4c-fe794fa84c80","keyword":"","originalKeyword":"飞灰"},{"id":"10052bd1-9c21-44f8-926a-a85184d5f56f","keyword":"固化","originalKeyword":"固化"}],"language":"zh","publisherId":"gsytb200805004","title":"土壤聚合物固化与水泥固化的比较研究","volume":"27","year":"2008"},{"abstractinfo":"以垃圾焚烧发电厂产生的为吸附剂,就对电镀废水中Cu2+的静态吸附特性进行了试验研究,着重探讨了平衡时间、pH值、剂量、溶液初始浓度等因素对Cu2+吸附效果的影响.结果表明,吸附处理电镀废水中Cu2+的吸附平衡时间为2 h;pH值是影响吸附废水中Cu2+的重要因素,pH=6时吸附效果最好,对Cu2+的去除率可达到87.01%;对Cu2+的吸附等温线较好地符合Henry模型和Freundlich模型,但不符合Langmuir模型.","authors":[{"authorName":"方明中","id":"ab98ef59-8c54-4a85-a350-0a8ac8d43e8d","originalAuthorName":"方明中"},{"authorName":"孙水裕","id":"d2dff736-caa9-4e93-ba1d-cb6f1e98c4d5","originalAuthorName":"孙水裕"},{"authorName":"陈华林","id":"a5d0bbe8-2d9b-4af7-800c-3987f942ec46","originalAuthorName":"陈华林"}],"doi":"10.3969/j.issn.1001-1560.2007.08.025","fpage":"76","id":"97e73dbc-85f1-407b-bf07-5c0c88bd448b","issue":"8","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"1d8d90f9-9303-469e-9d84-1851a4baa739","keyword":"","originalKeyword":"飞灰"},{"id":"ee8a32ac-e78e-45e6-997d-053e3d5d42e3","keyword":"吸附","originalKeyword":"吸附"},{"id":"b5d20afa-d712-4ea7-af40-de8a84e77bda","keyword":"电镀废水","originalKeyword":"电镀废水"},{"id":"7024bad6-c680-4384-9075-75641fa8c844","keyword":"Cu2+","originalKeyword":"Cu2+"},{"id":"a9aa655a-a472-4793-a5de-9d6d3c5f1c7f","keyword":"吸附等温线","originalKeyword":"吸附等温线"}],"language":"zh","publisherId":"clbh200708025","title":"吸附处理电镀废水中Cu2+的研究","volume":"40","year":"2007"}],"totalpage":114,"totalrecord":1138}