改性拜耳法赤泥颗粒的制备及对土壤铅的稳定化处理

杨慧珠, 程乾坤, 王新璋, 陈惠康, 张红云, 黄雄飞, 杨晓芳, 汤叶涛, 石太宏. 改性拜耳法赤泥颗粒的制备及对土壤铅的稳定化处理[J]. 环境工程学报, 2018, 12(4): 1171-1181. doi: 10.12030/j.cjee.201710029
引用本文: 杨慧珠, 程乾坤, 王新璋, 陈惠康, 张红云, 黄雄飞, 杨晓芳, 汤叶涛, 石太宏. 改性拜耳法赤泥颗粒的制备及对土壤铅的稳定化处理[J]. 环境工程学报, 2018, 12(4): 1171-1181. doi: 10.12030/j.cjee.201710029
YANG Huizhu, CHENG Qiankun, WANG Xinzhang, CHEN Huikang, ZHANG Hongyun, HUANG Xiongfei, YANG Xiaofang, TANG Yetao, SHI Taihong. Preparation of modified Bayer process red mud granules and stabilization treatment of lead in soil[J]. Chinese Journal of Environmental Engineering, 2018, 12(4): 1171-1181. doi: 10.12030/j.cjee.201710029
Citation: YANG Huizhu, CHENG Qiankun, WANG Xinzhang, CHEN Huikang, ZHANG Hongyun, HUANG Xiongfei, YANG Xiaofang, TANG Yetao, SHI Taihong. Preparation of modified Bayer process red mud granules and stabilization treatment of lead in soil[J]. Chinese Journal of Environmental Engineering, 2018, 12(4): 1171-1181. doi: 10.12030/j.cjee.201710029

改性拜耳法赤泥颗粒的制备及对土壤铅的稳定化处理

  • 基金项目:

    广东省科技开发协作项目(71010623)

Preparation of modified Bayer process red mud granules and stabilization treatment of lead in soil

  • Fund Project:
  • 摘要: 拜耳法赤泥产量大且成分复杂,碱性强,难处理,易引起环境污染。而近年土壤重金属污染形势严峻,儿童血铅中毒事件时有发生。针对上述问题,以拜耳法赤泥为主要原料,加入少量水泥等添加剂改性制备赤泥基颗粒材料,并将其应用于土壤中铅的稳定化。结果表明,材料配方为2%水泥+5%石膏+5%粉煤灰+5%磷酸二氢钙+83%,水灰比为0.5,圆盘造粒参数为28°﹣1﹣1时为颗粒最佳条件。按此配方制备的赤泥颗粒对铅污染浓度为100、250、500 和 800 mg·kg﹣1的模拟污染土壤进行修复,当投加5%的颗粒,稳定10 d后,土壤中铅的生物可利用态分别降低了72.52%、65.38%、64.73%和40.03%,而残渣态增加了43.4%、35.13%、43.42%和43.97%,有随着污土浓度增加而增加的趋势,表明赤泥制备成颗粒材料后能有效稳定土壤中不同浓度的铅。
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  • 刊出日期:  2018-04-22

改性拜耳法赤泥颗粒的制备及对土壤铅的稳定化处理

  • 1. 中山大学环境科学与工程学院,广州 510006
  • 2. 中电投山西铝业有限公司,原平 034100
  • 3. 广东省环境污染控制与修复技术重点实验室,广州 510006
基金项目:

广东省科技开发协作项目(71010623)

摘要: 拜耳法赤泥产量大且成分复杂,碱性强,难处理,易引起环境污染。而近年土壤重金属污染形势严峻,儿童血铅中毒事件时有发生。针对上述问题,以拜耳法赤泥为主要原料,加入少量水泥等添加剂改性制备赤泥基颗粒材料,并将其应用于土壤中铅的稳定化。结果表明,材料配方为2%水泥+5%石膏+5%粉煤灰+5%磷酸二氢钙+83%,水灰比为0.5,圆盘造粒参数为28°﹣1﹣1时为颗粒最佳条件。按此配方制备的赤泥颗粒对铅污染浓度为100、250、500 和 800 mg·kg﹣1的模拟污染土壤进行修复,当投加5%的颗粒,稳定10 d后,土壤中铅的生物可利用态分别降低了72.52%、65.38%、64.73%和40.03%,而残渣态增加了43.4%、35.13%、43.42%和43.97%,有随着污土浓度增加而增加的趋势,表明赤泥制备成颗粒材料后能有效稳定土壤中不同浓度的铅。

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