湿法磁选对粉煤灰中铁和重金属元素的分布影响研究
收稿日期: 2023-05-26
网络出版日期: 2024-04-18
基金资助
宁夏回族自治区重点研发计划项目(2022BDE02001);银川市科技计划项目(2022ZDGX11)
Study on effect of wet magnetic separation on distribution of Fe and heavy metal in fly ash
Received date: 2023-05-26
Online published: 2024-04-18
对煤粉锅炉粉煤灰(FA1灰)和循环流化床锅炉粉煤灰(FA2灰)采用湿法磁选的工艺达到降低其重金属含量的目的。利用扫描电子显微镜、激光粒度仪和X射线衍射仪表征两种粉煤灰在不同磁感应强度和不同磁选溶液浓度条件下磁选前后高磁性和弱磁性部分的形貌、粒度分布和物相分析,同时测定其铁元素和5种重金属元素(Hg、Pb、As、Cr、Cd)的含量变化,发现磁选后两种粉煤灰铁回收率随着磁感应强度增强而逐渐增加,高磁性组中重金属元素含量与弱磁性组有明显差异。结果表明:在磁感应强度为8 000 Gs和磁选溶液浓度为20%(质量分数)时,FA1的铁回收率为71.2%,FA2的铁回收率为47.0%。此时FA1磁选后Pb含量差值为0.2 mg/kg、Cr含量差值为9.2 mg/kg、As含量差值为1.1 mg/kg;FA2磁选后Pb含量差值为18.1 mg/kg、Cr含量差值为25.0 mg/kg、As含量差值为9.1 mg/kg。
李快 , 栗照帅 , 董庭轩 , 李丹 , 郭生伟 , 韩凤兰 . 湿法磁选对粉煤灰中铁和重金属元素的分布影响研究[J]. 无机盐工业, 2024 , 56(4) : 98 -104 . DOI: 10.19964/j.issn.1006-4990.2023-0289
A wet magnetic separation process was used for pulverized coal boiler fly ash(FA1 ash) and circulating fluidized bed boiler fly ash(FA2 ash) to reduce their heavy metal content.Scanning electron microscope,laser particle sizer and X-ray diffractometer were used to characterize the morphology,particle size distribution and physical phase analysis of the highly magnetic and weakly magnetic parts of the two types of fly ash before and after magnetic separation under the conditions of different magnetic induction strengths and different concentrations of magnetic separation solutions,and to determine the changes in the contents of iron and five heavy metal elements(Hg,Pb,As,Cr,Cd).It was found that the iron recovery rate of the two types of fly ash after magnetic separation was increased gradually with the increase of magnetic induction strength,and the content of heavy metal elements in the high magnetic group was significantly different from that in the weak magnetic group.The results showed that the Fe recovery of FA1 was 71.2% and that of FA2 was 47.0% at the magnetic induction intensity of 8 000 Gs and the magnetic separation solution concentration of 20%.At this time,the difference of Pb content,Cr content and As content after magnetic separation of FA1 was 0.2 mg/kg,9.2 mg/kg and 1.1 mg/kg,respectively.The difference of Pb content,Cr content and As content after magnetic separation of FA2 was 18.1 mg/kg,25.0 mg/kg and 9.1 mg/kg,respectively.
| 1 | LUO Yang, WU Yinghong, MA Shuhua, et al. Utilization of coal fly ash in China:A mini-review on challenges and future directions[J]. Environmental Science and Pollution Research, 2021, 28(15):18727-18740. |
| 2 | 张祥成, 孟永彪. 浅析中国粉煤灰的综合利用现状[J]. 无机盐工业, 2020, 52(2):1-5. |
| ZHANG Xiangcheng, MENG Yongbiao. Brief analysis on present situation of comprehensive utilization of fly ash in China[J]. Inorganic Chemicals Industry, 2020, 52(2):1-5. | |
| 3 | 冯文丽, 吕学斌, 熊健, 等. 粉煤灰高附加值利用研究进展[J]. 无机盐工业, 2021, 53(4):25-31. |
| FENG Wenli, Xuebin Lü, XIONG Jian, et al. Research progress of high added value utilization of coal fly ash[J]. Inorganic Chemicals Industry, 2021, 53(4):25-31. | |
| 4 | STRZA?KOWSKA E. Morphology,chemical and mineralogical composition of magnetic fraction of coal fly ash[J]. International Journal of Coal Geology, 2021, 240:103746. |
| 5 | VALEEV D, KUNILOVA I, ALPATOV A, et al. Magnetite and carbon extraction from coal fly ash using magnetic separation and flotation methods[J]. Minerals, 2019, 9(5):320. |
| 6 | LIU Huidong, SUN Qi, WANG Baodong, et al. Morphology and composition of microspheres in fly ash from the Luohuang power plant,Chongqing,southwestern China[J]. Minerals, 2016, 6(2):30. |
| 7 | MA Yongbo, DU Xueyan, SHEN Yingying, et al. Crystallization and beneficiation of magnetite for iron recycling from nickel slags by oxidation-magnetic separation[J]. Metals, 2017, 7(8):321. |
| 8 | WANG Guxia, LI Zhaoshuai, YAN Jun, et al. Value-added utilization of coal fly ash in polymeric composite decking boards[J]. Journal of Materials Research and Technology, 2023, 23:4199-4210. |
| 9 | 刘大锐, 许立军, 李世春, 等. 粉煤灰中战略金属锂的回收研究进展[J]. 无机盐工业, 2023, 55(1):56-63. |
| LIU Darui, XU Lijun, LI Shichun, et al. Research progress of recovery of strategic metal lithium from fly ash[J]. Inorganic Chemicals Industry, 2023, 55(1):56-63. | |
| 10 | 郑彬, 蒋亮, 韩凤兰, 等. 铜渣复合硅锰水淬渣后的改质提铁研究[J]. 无机盐工业, 2023, 55(1):136-143. |
| ZHENG Bin, JIANG Liang, HAN Fenglan, et al. Study on reformation and extracting iron of copper slag and silicon-manganese water quenched slag composites[J]. Inorganic Chemicals Industry, 2023, 55(1):136-143. | |
| 11 | LU S G, CHEN Y Y, SHAN H D, et al. Mineralogy and heavy metal leachability of magnetic fractions separated from some Chinese coal fly ashes[J]. Journal of Hazardous Materials, 2009, |
| 169 ( 1/ 2/3):246-255. | |
| 12 | PETRUS H T B M, OLVIANAS M, SUPRAPTA W, et al. Cenospheres characterization from Indonesian coal-fired power plant fly ash and their potential utilization[J]. Journal of Environmental Chemical Engineering, 2020, 8(5):104116. |
| 13 | KUKIER U, ISHAK C F, SUMNER M E, et al. Composition and element solubility of magnetic and non-magnetic fly ash fractio--ns[J]. Environmental Pollution, 2003, 123(2):255-266. |
| 14 | ROSITA W, BENDIYASA I M, PERDANA I, et al. Sequential particle-size and magnetic separation for enrichment of rare-earth elements and yttrium in Indonesia coal fly ash[J]. Journal of Environmental Chemical Engineering, 2020, 8(1):103575. |
| 15 | NI Peng, LI Hailong, ZHAO Yongchun, et al. Relation between leaching characteristics of heavy metals and physical properties of fly ashes from typical municipal solid waste incinerators[J]. Environmental Technology, 2017, 38(17):2105-2118. |
| 16 | LANZERSTORFER C. Fly ash from coal combustion:Dependen-ce of the concentration of various elements on the particle size[J]. Fuel, 2018, 228:263-271. |
| 17 | BAKALáR T, PAVOLOVá H, HAJDUOVá Z, et al. Metal recovery from municipal solid waste incineration fly ash as a tool of circular economy[J]. Journal of Cleaner Production, 2021, 302:126977. |
| 18 | LIU Fuli, MA Shuhua, REN Kun, et al. Mineralogical phase separation and leaching characteristics of typical toxic elements in Chinese lignite fly ash[J]. Science of the Total Environment, 2020, 708:135095. |
| 19 | 韩大捷, 马淑花, 王晓辉, 等. 硝酸脱除褐煤粉煤灰中的砷[J]. 过程工程学报, 2018, 18(4):716-721. |
| HAN Dajie, MA Shuhua, WANG Xiaohui, et al. Removal of arsenic in lignite fly ash by nitric acid[J]. The Chinese Journal of Process Engineering, 2018, 18(4):716-721. | |
| 20 | WEI Yunmei, MEI Xiaoxia, SHI Dezhi, et al. Separation and characterization of magnetic fractions from waste-to-energy bottom ash with an emphasis on the leachability of heavy metals[J]. Environmental Science and Pollution Research, 2017, 24(17):14970-14979. |
| 21 | 王尚杰夫, 金会心, 雷二帅, 等. 赤泥、粉煤灰和磷石膏配碳碱性调控共烧结回收铁铝[J]. 中国冶金, 2023, 33(4):119-126. |
| WANG Shangjiefu, JIN Huixin, LEI Ershuai, et al. Recovery of iron and aluminum from red mud,fly ash and phosphogypsum by co-sintering under alkaline control of carbon addition[J]. China Metallurgy, 2023, 33(4):119-126. |
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