一氧化碳脱毒铬渣制备水泥矿物掺合料
收稿日期: 2020-08-13
网络出版日期: 2021-05-12
基金资助
国家自然基金(61102041);辽宁省高校创新团队支撑计划(2013010);国家科技支撑计划(2013BAB09B01);辽宁省教育厅项目(L2013169);辽宁省精细化工协同创新中心资助项目;辽宁省自然基金(201602582);辽宁省自然科学基金指导计划项目:基于涡致振动的宽带压电能量收集结构研究(2019-ZD-0075);国家重点研发计划(2017YFC0210504);西部典型产业环境污染控制协同创新中心开放基金(XTCX-2014-01)
Preparation of cement mineral admixture from chromium slag detoxified by carbon monoxide
Received date: 2020-08-13
Online published: 2021-05-12
实验研究了模拟一氧化碳工业废气解毒的脱毒铬渣制备水泥矿物掺合料时,其添加比对胶砂试件抗压、抗折强度及凝结时间的影响,测定了试件中总铬(Cr)和六价铬Cr(Ⅵ)浸出浓度,并采用半动态浸出实验测定其有效扩散系数D和扩散因子L。结果表明,细磨后的脱毒铬渣符合水泥矿物掺合料的性能要求,随着添加比例的增加,胶砂凝结时间增加,抗压、抗折强度下降,但各实验组试件均达到C60的强度等级要求。试件中Cr(Ⅵ)和总Cr的D值达到10-10~10-9数量级,L值>9,迁移能力极低,证明制备矿物掺合料是一种安全有效的脱毒铬渣资源化处置方法。
何力为 , 周学进 , 宁平 . 一氧化碳脱毒铬渣制备水泥矿物掺合料[J]. 无机盐工业, 2021 , 53(5) : 73 -77 . DOI: 10.11962/1006-4990.2020-0366
The influence of the addition ratio of chromium slag detoxified by carbon monoxide off-gas on the compressive strength,bending strength and setting time of concrete test samples were experimentally studied.The leaching concentrations of total chromium(Cr) and hexavalent chromium Cr(Ⅵ)were determined,and their effective diffusion co-efficient D and diffu-sion factor L were calculated by semi-dynamic leaching experiment.The results showed that the detoxified chromium slag after fine grinding could meet the requirement of cement mineral admixture.With the increase of adding ratio,the setting time of mortar were extended,the compressive and bending strength were declined,but all the experimental groups meet the strength grade requirements of C60.The D value of Cr(Ⅵ) and total Cr in the sample was 10-10~10-9,L value was more than 9,and the migration ability was very low,which proved that the preparation of mineral admixtures was a safe and effective resource disposal method for detoxified chromium slag.
| [1] | 纪柱. 中国铬盐近五十年发展概况[J]. 无机盐工业, 2010,42(12):1-15. |
| [2] | Walawska B, Kowalski Z. Model of technological alternatives of pro-duction of sodium chromate(Ⅵ) with the use of chromic wastes[J]. Waste Management, 2000,20(8):711-723. |
| [3] | Hori M, Shozugawa K, Matsuo M. Hexavalent chromium pollution caused by dumped chromium slag at the urban park in Tokyo[J]. Journal of Material Cycles & Waste Management, 2015,17(1):201-205. |
| [4] | Matern K, Weigand H, Singh A, et al. Environmental status of gro-undwater affected by chromite ore processing residue(COPR) dum-psites during pre-monsoon and monsoon seasons[J]. Environmental Science & Pollution Research, 2017,24(4):3582-3592. |
| [5] | 刘帅霞. 两段式还原工艺解毒铬渣技术研究[D]. 上海:东华大学, 2013. |
| [6] | Li Y, Cundy A B, Feng J, et al. Remediation of hexavalent chromium contamination in chromite ore processing residue by sodium dithio-nite and sodium phosphate addition and its mechanism[J]. Journal of Environmental Management, 2017,192(5):100-106. |
| [7] | Panneerselvam P, Choppala G, Kunhikrishnan A, et al. Potential of novel bacterial consortium for the remediation of chromium contam-ination[J]. Water,Air,and Soil Pollution, 2013,224(12):211-221. |
| [8] | Chen J, Wang Y, Zhou S, et al. Reduction/immobilization processes of hexavalent chromium using metakaolin-based geopolymer[J]. Jour-nal of Environmental Chemical Engineering, 2016,4(2):2084-2089. |
| [9] | 何力为, 李彬, 宁平, 等. 利用一氧化碳工业废气解毒铬渣的方法及条件优化[J]. 环境工程学报, 2018,12(9):195-204. |
| [10] | Bagheri A, Nazari A. Compressive strength of high strength class C fly ash-based geopolymers with reactive granulated blast furnace slag aggregates designed by Taguchi method[J]. Materials & De-sign, 2014,54(2):483-490. |
| [11] | He L, Li B, Ning P, et al. Chromium slag detoxification by carbon monoxide off-gases and optimization of detoxification parameters by Box-Behnken design[J]. Journal of Material Cycles and Waste Management, 2019,22(3):111-122. |
| [12] | 白智韬, 邱桂博, 彭犇, 等. 高碳铬铁渣基微晶玻璃体系调控分析[J]. 环境工程, 2019,37(1):158-163. |
| [13] | 方久华, 杨峰, 左明扬, 等. 玻璃配合料中铬渣最大允许用量研究[J]. 无机盐工业, 2015,47(1):18-21. |
| [14] | 冯勇, 韩艳丽. 钢渣混凝土抗硫酸盐、镁盐侵蚀性能的实验分析[J]. 硅酸盐通报, 2015,34(11):3345-3351. |
| [15] | Jagupilla S C, Moon D H, Wazne M, et al. Effects of particle size and acid addition on the remediation of chromite ore processing re-sidue using ferrous sulfate[J]. Journal of Hazardous Materials, 2009,168(1):121-128. |
| [16] | Chrysochoou M, Fakra S C, Marcus M A, et al. Microstructural an-alyses of Cr(Ⅵ) speciation in chromite ore processing residue (COPR)[J]. Environmental Science & Technology, 2009,43(14):5461-5466. |
| [17] | GB/T 17671—1999 水泥胶砂强度实验[S]. |
| [18] | GB/T 7023—2011 低、中水平放射性废物固化体标准浸出实验方法[S]. |
| [19] | HJ/T 299—2007 固体废物浸出毒性浸出方法硫酸硝酸法[S]. |
| [20] | GB/T 15555.4—1995 固体废物六价铬的测定二苯碳酰二肼分光光度法[S]. |
| [21] | HJ 687—2014 固体废物六价铬的测定碱消解/火焰原子吸收分光光度法[S]. |
| [22] | HJ/T 301—2007 铬渣污染治理环境保护技术规范(暂行)[S]. |
| [23] | GB/T 203—2008 用于水泥中的粒化高炉矿渣[S]. |
| [24] | GB/T 2847—2005 用于水泥中的火山灰质混合材料[S]. |
| [25] | GB 175—2007 通用硅酸盐水泥[S]. |
| [26] | Dutre V, Vandecasteele C. An evaluation of the solidification/stabi-lization of industrial arsenic containing waste using extraction and semi-dynamic leach tests[J]. Waste Management, 1996,16(7):625-631. |
/
| 〈 |
|
〉 |
