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  4. 现代转炉炼钢各工序炉渣的再利用研究综述

中国冶金, 2010, 20(12): 43-47.

现代转炉炼钢各工序炉渣的再利用研究综述

樊君 1, , 赵俊学 2, , 陈艳梅 3, , 刘立 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"},"keywords":[{"id":"fc49fd3d-8fa9-4cbe-931a-4119911ca984","keyword":"水性涂料","originalKeyword":"水性涂料"},{"id":"20ef823a-13ad-455e-aef7-908eb6ff73e9","keyword":"二氧化钛颜料","originalKeyword":"二氧化钛颜料"},{"id":"92f9c2d6-291d-4dae-9e2b-2fe4667b56e7","keyword":"颜色测定","originalKeyword":"颜色测定"},{"id":"c98d687a-cead-4999-a54b-d25af3a498f6","keyword":"色度","originalKeyword":"色度法"},{"id":"a5934ce0-f2f8-46ec-8187-87d75d169f01","keyword":"干膜","originalKeyword":"干膜"}],"language":"zh","publisherId":"ddyts201104019","title":"水性涂料中二氧化钛颜料颜色的测定","volume":"30","year":"2011"},{"abstractinfo":"根据金纳米粒子等离子体共振吸收引起的溶液颜色变化,建立了一种快速、简便检测头孢唑啉的色度分析方法.方法线性范围为0.1~5.0 μmol/L,检测限为14 nmol/L.将该方法用于头孢唑啉钠粉针剂的分析,回收率在97.4%~100.2%之间,相对标准偏差小于6.1%.","authors":[{"authorName":"李靖云","id":"b71dc1eb-bab5-4ce8-8d14-f5622c8dcc07","originalAuthorName":"李靖云"},{"authorName":"王燚","id":"a4d330b6-3d05-4f27-8060-9cbe8996dbbf","originalAuthorName":"王燚"},{"authorName":"许佳丽","id":"85d55791-943a-40e3-9b32-d2305580f8a9","originalAuthorName":"许佳丽"},{"authorName":"李原芳","id":"a60e9766-31ab-4e7b-9df7-99a490c2fcbf","originalAuthorName":"李原芳"}],"doi":"10.3724/SP.J.1095.2012.00231","fpage":"455","id":"cca8781d-45b0-4ac6-957d-11ce631700c1","issue":"4","journal":{"abbrevTitle":"YYHX","coverImgSrc":"journal/img/cover/YYHX.jpg","id":"73","issnPpub":"1000-0518","publisherId":"YYHX","title":"应用化学"},"keywords":[{"id":"90a383cb-402b-4fa8-b0b7-0c0e0a6c185b","keyword":"金纳米颗粒","originalKeyword":"金纳米颗粒"},{"id":"bea70a25-32d3-40f6-bdcd-18e96ab25393","keyword":"头孢唑啉","originalKeyword":"头孢唑啉"},{"id":"fb51f7e7-e143-483f-a325-f63b32ff5580","keyword":"氯化钠","originalKeyword":"氯化钠"},{"id":"7708f203-fc95-4094-a216-f1ffbb52b342","keyword":"等离子体共振吸收","originalKeyword":"等离子体共振吸收"},{"id":"28122604-8337-4cba-ba91-1b07ad97ba3e","keyword":"色度","originalKeyword":"色度法"}],"language":"zh","publisherId":"yyhx201204015","title":"金纳米颗粒等离子体共振吸收光谱检测头孢唑啉","volume":"29","year":"2012"},{"abstractinfo":"采用曝气生物膜深度处理已有工艺中曝气池排出的染料废水(COD 300 mg/L,色度280).重点考察了气水比、水力负荷和滤床高度对色度去除率的影响.结果表明:曝气生物膜深度处理染料废水是可行的,在气水比为1.5:1、水力负荷为1.0 m3/(m2·h)条件下,经过BAF反应器深度处理后出水色度为41.2,去除率为85.3%,达到《纺织染整工业水污染物排放标准》GB 4287-92一级排放标准;此外滤床高度对色度的去除也有着重要影响,色度的去除主要发生在0~0.8 m高度范围内,去除率达到84.8%.和其它技术相比,采用曝气生物膜处理染料废水具有成本低、运行管理方便和占地面积小等特点,可为同类废水处理提供参考.","authors":[{"authorName":"邹海明","id":"fcdb4993-2693-4c19-afbe-073fc7615b94","originalAuthorName":"邹海明"},{"authorName":"于群英","id":"d1f1d7b6-75af-4791-8c4d-d3fa6fd3641a","originalAuthorName":"于群英"},{"authorName":"王艳","id":"2f54f1bb-8960-4b8c-a1c1-61bffa58db4e","originalAuthorName":"王艳"},{"authorName":"李飞跃","id":"d77c1d25-7f13-446b-a8fb-8af51caba2df","originalAuthorName":"李飞跃"}],"doi":"","fpage":"105","id":"f08ae12f-0741-4750-ad85-cf4a0c19232d","issue":"6","journal":{"abbrevTitle":"MKXYJS","coverImgSrc":"journal/img/cover/MKXYJS.jpg","id":"54","issnPpub":"1007-8924","publisherId":"MKXYJS","title":"膜科学与技术 "},"keywords":[{"id":"7c661abb-5866-4e36-bbb9-22179cce4438","keyword":"染料废水","originalKeyword":"染料废水"},{"id":"a218d4d5-f944-4784-8963-52d6c807d85d","keyword":"生物膜","originalKeyword":"生物膜"},{"id":"c53bc5fc-7176-496d-bbc7-4bb428d746ef","keyword":"深度处理","originalKeyword":"深度处理"},{"id":"a77610e8-275f-442e-a420-6af25b102d99","keyword":"曝气生物滤池","originalKeyword":"曝气生物滤池"},{"id":"bc4644a0-4a1c-41a9-90f0-320fc1dc5c78","keyword":"色度","originalKeyword":"色度"}],"language":"zh","publisherId":"mkxyjs201206019","title":"曝气生物膜深度去除染料废水色度应用研究","volume":"32","year":"2012"},{"abstractinfo":"建立了可降解包装材料的绿色度评价指标体系,运用模糊层次分析模型对其进行了评价和分析.通过问卷调查得到定性评价后,利用概率统计的原理对数据进行了处理,构造比较矩阵,并采用和积计算最大特征根和特征向量,最终得到各指标的相对重要度.然后又计算得到各指标相对于被评价产品的综合重要度.用逻辑推理指派确定各指标的隶属函数后,得到该指标的隶属度.根据各评价指标的隶属度和综合重要度运用线形加权的方法得到的植物纤维淀粉可降解包装材料的绿色度.最后把6种典型可降解包装材料和传统发泡塑料包装材料的绿色度进行了对比,认为生物质类可降解包装材料具有很好的发展前景.","authors":[{"authorName":"郭安福","id":"72902230-10f1-4cd3-b1c9-00c689991a00","originalAuthorName":"郭安福"},{"authorName":"李剑峰","id":"433ac6fc-a733-428c-8a6c-ca44785e84fc","originalAuthorName":"李剑峰"},{"authorName":"李方义","id":"e1083c1d-f066-41b0-8393-a80dd1a075b5","originalAuthorName":"李方义"},{"authorName":"魏宝坤","id":"b31c967d-606a-408e-ab16-99272aee9524","originalAuthorName":"魏宝坤"}],"doi":"","fpage":"401","id":"4b419c36-f229-4d93-9eac-6443e9aea61b","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":"16fee74c-6aba-4bd7-83db-1cd9cf0acb39","keyword":"可降解包装材料","originalKeyword":"可降解包装材料"},{"id":"2d69dfe9-2052-4b73-99b8-7d56161e662c","keyword":"模糊层次分析","originalKeyword":"模糊层次分析法"},{"id":"e77c4337-76a9-41ea-bafb-23db7602000b","keyword":"生命周期评价","originalKeyword":"生命周期评价"}],"language":"zh","publisherId":"gncl201003011","title":"基于模糊层次分析的可降解包装材料绿色度评价","volume":"41","year":"2010"},{"abstractinfo":"根据色度学原理,利用USB2000+光纤光谱仪,量化红宝石颜色的主波长或补色波长、色调角以及颜色描述的分析可知:色调角h*ab在(0°,18°),补色波长λc为490~ 496 nm时,红宝石色调为红色;色调角hab*在(342°,360°),补色波长λc为497~509 nm时,红宝石色调为粉红色;色调角h*ab在(324°,342°),补色波长λc为509 ~ 542nm时,红宝石色调为紫红色;色调角h*ab在(306°,324°),补色波长λc为542~ 570 nm时,红宝石色调为紫色.因此,利用光纤光谱仪、适当的照明方式及光谱采集方法,应用色度学原理,可以客观、定量地描述红宝石的颜色,可作为评价红宝石颜色的适用技术.","authors":[{"authorName":"董琳玲","id":"30370a75-bd0e-4fd1-bda4-a69eaa8c1670","originalAuthorName":"董琳玲"},{"authorName":"祖恩东","id":"c637cca9-0158-4934-b9d9-f8f77a3a809d","originalAuthorName":"祖恩东"},{"authorName":"贺晓","id":"95e9ed75-9af7-4249-9039-553b67e1ca08","originalAuthorName":"贺晓"},{"authorName":"唐雪莲","id":"076fe433-0cd3-4725-a16d-166d60110d93","originalAuthorName":"唐雪莲"}],"doi":"","fpage":"2169","id":"79d13f76-90be-427c-839d-5cf948de1038","issue":"10","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"c4ebd306-9f99-4cda-99c6-617b8b29d38e","keyword":"红宝石","originalKeyword":"红宝石"},{"id":"e108a21c-9c6f-42d8-848f-966709c87495","keyword":"色度学","originalKeyword":"色度学"},{"id":"90e53769-708b-4404-89c8-04f227d42c12","keyword":"色调角","originalKeyword":"色调角"},{"id":"0e1f993a-1126-46a0-8a22-4d2f5d754e8c","keyword":"补色波长","originalKeyword":"补色波长"}],"language":"zh","publisherId":"gsytb201310045","title":"红宝石的色度学研究","volume":"32","year":"2013"},{"abstractinfo":"为了对显示器进行色度特性化,探讨了显示器颜色控制值RGB与其CIE系统X、Y、Z颜色三刺激值之间的对应关系.根据显示器通道色光的光谱比例不变性,确定了每个通道的色度比常数,由此将红、绿、蓝通道的数字量R、G、B分别与其色光的Xr、Yg、Zb(称为主颜色刺激值)相关联,再将复色光的颜色刺激CIE XYZ与各通道的主刺激Xr、Yg、Zb建立联系.在一个LCD和一个CRT显示器上的应用结果表明,对729个检验颜色分别得到了4.74和1.48的CIELAB色差,表明该方法具有较高的显示器色度颜色转换精度.","authors":[{"authorName":"徐艳芳","id":"6fb2a212-54df-4e07-9e8d-78aaf381c3d3","originalAuthorName":"徐艳芳"},{"authorName":"黄敏","id":"7d9e58f9-88bc-4c19-a775-4fc770a0207f","originalAuthorName":"黄敏"},{"authorName":"金杨","id":"858fdc17-b287-4eaa-9206-25c47337c4af","originalAuthorName":"金杨"}],"doi":"10.3969/j.issn.1007-2780.2008.06.025","fpage":"771","id":"c88a7b52-55e6-485d-8763-c43802b17f34","issue":"6","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"0a462597-2cd3-4428-abdb-c4261fffe2ef","keyword":"色度学","originalKeyword":"色度学"},{"id":"b56d4462-1481-4482-94a3-f9f40afdb952","keyword":"颜色特性化","originalKeyword":"颜色特性化"},{"id":"e8bec2d5-9c38-46ec-8128-4742cabe057f","keyword":"颜色转换","originalKeyword":"颜色转换"},{"id":"5f9dcb8a-14ac-422e-863d-8c7d3e364aaa","keyword":"色度比","originalKeyword":"色度比"},{"id":"00d17f97-9fdb-4de4-bb1f-782f470fe7a2","keyword":"色差","originalKeyword":"色差"}],"language":"zh","publisherId":"yjyxs200806025","title":"基于色度比特性的显示器色度特性化","volume":"23","year":"2008"},{"abstractinfo":"  评述了合金元素对Au的漂白效果和机制,介绍了白色开金的几种色度参数,如CIE-L a*b*色度参数和颜色盒,CIE-LAB-C-H-L米制色度参数和基于CIE-XYZ色度参数的ASTM D1925黄色指数YI,讨论了某些白色开金的色度参数与冶金学特征。基于金合金的漂白效应与合金成分的密切关系,ASTM D1925黄色指数YI为设计白色开金成分提供了基本的指南。","authors":[{"authorName":"宁远涛","id":"cbebd336-3bb6-4cee-9205-bf9f0707fcca","originalAuthorName":"宁远涛"}],"doi":"","fpage":"71","id":"75b19b01-23af-4d47-a95a-414b4c44395b","issue":"2","journal":{"abbrevTitle":"GJS","coverImgSrc":"journal/img/cover/GJS.jpg","id":"38","issnPpub":"1004-0676","publisherId":"GJS","title":"贵金属"},"keywords":[{"id":"cf470a57-d61e-4355-8431-877f867e9e5d","keyword":"金属材料","originalKeyword":"金属材料"},{"id":"0e337e45-b08f-4f2d-836c-54719dc64402","keyword":"Au合金","originalKeyword":"Au合金"},{"id":"c92710af-4292-4223-a9ff-726953207a3a","keyword":"白色开金","originalKeyword":"白色开金"},{"id":"c393fab0-c1ec-4bdc-8121-89e733255e3a","keyword":"色度参数","originalKeyword":"色度参数"},{"id":"db78d9ac-bf6d-418b-ab6b-5cb6f4884f5d","keyword":"色度图","originalKeyword":"色度图"}],"language":"zh","publisherId":"gjs201302017","title":"白色开金的色度参数和白色分级","volume":"","year":"2013"},{"abstractinfo":"作者研究了乌铜的着色过程、保护膜色度的变化规律,探讨了成色机理.结果表明Cu2+和Cl-是乌铜着色剂中不可少的离子,乌铜着色色度(黑度)随着含Au量的增加而变化;在着色时其表面先生成Cu2O膜,并在Au的催化作用下很快转化为CuO.","authors":[{"authorName":"许昆","id":"c6176cd1-8906-4ca2-b7bb-0c5683336264","originalAuthorName":"许昆"}],"doi":"10.3969/j.issn.1004-0676.2003.02.007","fpage":"28","id":"b5f1b785-86fb-4d02-8a37-cdac6e8afe92","issue":"2","journal":{"abbrevTitle":"GJS","coverImgSrc":"journal/img/cover/GJS.jpg","id":"38","issnPpub":"1004-0676","publisherId":"GJS","title":"贵金属"},"keywords":[{"id":"11792deb-1d7c-4d42-815a-9b7452909226","keyword":"金属材料","originalKeyword":"金属材料"},{"id":"ddfaabd1-f20b-410c-b7fa-29278844d84f","keyword":"铜合金","originalKeyword":"铜合金"},{"id":"3e2542df-3b94-4c4c-8b92-87159edfb085","keyword":"乌铜","originalKeyword":"乌铜"},{"id":"30123a17-df8f-4c78-b6f3-8a1c8215b8bc","keyword":"色度","originalKeyword":"色度"},{"id":"fd70cd64-f973-463f-b589-8ca40d46c98c","keyword":"成色机理","originalKeyword":"成色机理"}],"language":"zh","publisherId":"gjs200302007","title":"乌铜保护膜色度和成色机理探讨","volume":"24","year":"2003"},{"abstractinfo":"利用淤泥、污泥等废弃物生产绿色轻集料产品已成为当前的一个研究热点.但目前对轻集料产品的绿色度尚无科学适用的评价方法.本文利用模糊数学方法,以轻集料产品的生产效率、产品质量、综合成本、资源消耗及其对环境的影响等五个因素为评价指标,建立了简便有效的轻集料产品相对绿色度评价模型,利用该模型可对各种轻集料的绿色度进行评价.","authors":[{"authorName":"胡曙光","id":"791afcec-5091-4c17-b5cb-c6c5105faab3","originalAuthorName":"胡曙光"},{"authorName":"黄劲","id":"245aa3f6-7459-4a0a-8e4e-b53e53426a10","originalAuthorName":"黄劲"},{"authorName":"王发洲","id":"9698607b-fb7c-479e-b9f8-0cb7c0f95921","originalAuthorName":"王发洲"}],"doi":"10.3969/j.issn.1001-1625.2006.05.015","fpage":"64","id":"ffccbaf4-8d26-49e8-bb64-a5fc6c9b1c24","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":"c849edc3-2e63-4b66-b97e-2aaa7047029f","keyword":"轻集料","originalKeyword":"轻集料"},{"id":"dd0b2985-45c7-4369-98ca-2c4041738e61","keyword":"绿色度","originalKeyword":"绿色度"},{"id":"22b638b5-13d6-42cc-82f2-b38889009f36","keyword":"评价方法","originalKeyword":"评价方法"},{"id":"850eb216-eb88-4e09-bc97-3fd95718161f","keyword":"模糊数学","originalKeyword":"模糊数学"}],"language":"zh","publisherId":"gsytb200605015","title":"轻集料绿色度评价方法的建立及应用","volume":"25","year":"2006"},{"abstractinfo":"彩色滤光膜(CF)色度指标对彩色液晶显示器的显示性能有着重要的影响,采用传统的分光光度计测量CF光谱透过率存在着严重的混光现象,研究分析了CF色度参数的表征与测试原理,设计了高精度的显微光谱测试系统.系统能够精密测试50 μm尺寸样品的光谱特性,并且得到±0.005的色度座标测试精度.系统已应用在彩色滤光膜与彩色液晶显示器生产企业,取得了良好的效果.","authors":[{"authorName":"张航","id":"6653aaf9-c64a-417e-81f4-59a623018c3f","originalAuthorName":"张航"},{"authorName":"于涛","id":"176ad4b2-2e2f-472b-a18c-d57d0b4b9765","originalAuthorName":"于涛"},{"authorName":"张睿鹏","id":"55d49d23-4bd3-4629-ae11-3110f43c85b6","originalAuthorName":"张睿鹏"}],"doi":"10.3969/j.issn.1007-2780.2005.04.015","fpage":"337","id":"ee78c32e-2420-45e8-8b36-93d003dc725e","issue":"4","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"2bdd1ab8-e007-45f6-be1d-24376b65558f","keyword":"彩色滤光膜","originalKeyword":"彩色滤光膜"},{"id":"d9b2af7f-1ed6-4714-b996-f8dec6258559","keyword":"测试系统","originalKeyword":"测试系统"},{"id":"79707a51-d73c-47df-b922-e140757287e9","keyword":"显微光谱测试","originalKeyword":"显微光谱测试"},{"id":"eba03bcf-2ac6-4505-8688-c431dfadda8c","keyword":"色度座标","originalKeyword":"色度座标"}],"language":"zh","publisherId":"yjyxs200504015","title":"彩色滤光膜色度测试系统的研究","volume":"20","year":"2005"}],"totalpage":3354,"totalrecord":33538}