Stabilization of Heavy Metals in Municipal Sludge Using a Slag-Based Modifying Agent

被引：0

作者：

Zhang F.-W. ^{[1
]}

Dong M.-K. ^{[1
]}

Chen C.-H. ^{[1
]}

Zhao C.-M. ^{[2
]}

机构：

[1] College of Forestry, Henan Agricultural University, Zhengzhou

[2] Zhengzhou Ecological Environment Monitoring Center, Zhengzhou

来源：

Huanjing Kexue/Environmental Science | 2021年 / 42卷 / 07期

关键词：

Heavy metals; Modifying; Morphology; Sludge; Stability efficiency;

D O I：

10.13227/j.hjkx.202008202

中图分类号：

学科分类号：

摘要：

Taking urban domestic sludge as the research object, a slag-based modifying agent was used to modify sludge under different dosages and curing times, and the solidification effect of six heavy metals in the sludge, namely Zn, Cr, Cu, Pb, As, and Cd, were evaluated by analyzing stability efficiency and morphological changes. The results showed that the stability efficiency improved as curing time and dosage increased, reaching the maximum when the curing time was 14 d and the dosage was 50%. Under these conditions, Cu reached the maximum of 69.62%, and the most rapid growth was observed when dosages were 5%-20%. Through the regression analysis of adding amount, maintenance time and stability efficiency, it was found that the fitting correlation coefficient Cu was the highest 0.97, with a strong degree of fitting and a strong interaction between adding amount and maintenance time, which had a significant influence on the stability efficiency. In addition, Pb and As were the residual state, Cu and Cr were oxidizable state and residue state, Zn and Cd were reducible and extractable state as the main forms in the sludge after modifying, respectively. With the increase of curing time or dosage, the residual state of each heavy metal increased by 7%-86%. The results showed that the slag-based modifying agent could effectively solidify heavy metals in sludge and reused solid wastes such as sludge. © 2021, Science Press. All right reserved.

引用

页码：3430 / 3441

页数：11

共 36 条

[1] Tian Z K, Wang F, Yan Z., Effects of mesophilic anaerobic digestion and thermophilic anaerobic digestion on the risk and stability of heavy metals in sludge, Environmental Science, 41, 11, pp. 5106-5113, (2020)
[2] Xie D L, Kong C M, Xu L Q, Et al., Developments of the speciation, removal and stabilization of heavy metals in municipal sludge, Chemical Industry and Engineering Progress, 37, 1, pp. 330-342, (2018)
[3] Du F Z, Freguia S, Yuan Z G, Et al., Enhancing toxic metal removal from acidified sludge with nitrite addition, Environmental Science & Technology, 49, 10, pp. 6257-6263, (2015)
[4] Wang W B., Preparation of magnesium phosphate cement mixed with sludge and study on its solidification of heavy metals, (2018)
[5] Li X, Song Y, Liu Y B., Leaching behavior of Pb, Cd and Zn from soil stabilized by lime stabilized sludge, Environmental Science, 35, 5, pp. 1946-1954, (2014)
[6] Samaras P, Papadimitriou C A, Haritou I, Et al., Investigation of sewage sludge stabilization potential by the addition of fly ash and lime, Journal of Hazardous Materials, 154, 1-3, pp. 1052-1059, (2008)
[7] Lim S, Jeon W, Lee J, Et al., Engineering properties of water/wastewater-treatment sludge modified by hydrated lime, fly ash and loess, Water Research, 36, 17, pp. 4177-4184, (2002)
[8] Graich A, Bellarbi A, Khaidar M, Et al., Using portland cement to stabilize/solidify sludge residue from treatment of cardboard plant wastewater, Journal of Hazardous, Toxic, and Radioactive Waste, 24, 3, (2020)
[9] Yan Q H, Ni W, Gao W, Et al., Mechanism for solidification of arsenic with blast furnace slag-steel slag based cementitious materials, Journal of Central South University (Science and Technology), 50, 7, pp. 1544-1550, (2019)
[10] Mao L Q., Solidification/stabilization of chromium-bearing electroplating sludge with alkali-activated cementitious materials, (2018)

← 1 2 3 4 →