Leaching characteristics of heavy metals and polycyclic aromatic hydrocarbons from permeable bricks prepared by pyrolysis residue of oily sludge

doi:10.16085/j.issn.1000-6613.2023-1324

Abstract

Abstract:

As a by-product of oil sludge pyrolysis, the stock of pyrolysis residue is increasing, which seriously threatens the ecological environment. Given that the composition of the pyrolysis residue of oily sludge was similar to that of clay minerals, in this study, pyrolysis residue was used to prepare water-permeating bricks instead of clay. The effects of pyrolysis residue addition amount, water amount and extrusion stress on the compressive strength and permeability of the prepared water-permeating bricks were investigated, and the concentration of heavy metals and polycyclic aromatic hydrocarbons (PAHs) in the leaching solution of permeated brick were also studied. The results show that the addition amount of pyrolysis residue, water amount and extrusion stress have significant impact on the compressive strength and permeability of the permeable brick. When the addition amount of pyrolysis residue is 15%, the amount of water is 13% and the extrusion stress is 30MPa, the physical properties of the permeable brick are the best. At this point, the compressive strength is 32.20MPa, reaching the Cc30 standard, and the permeable coefficient is 1.80×10^-2cm/s, which is higher than 1.00×10^-2cm/s specified in WaterPermeableBrick (JC/T 945—2005). The leaching experiment results of heavy metals and PAHs show that the metals detected in the leaching solution of water permeated brick include Cr, Pb, Cu, Ni and Zn. The concentrations of Cr, Cu and Zn are lower than the Class Ⅱ standard limits stipulated in the EnvironmentalQualityStandardforSurfaceWater (GB 3838—2002) and the class Ⅲ standard limits stipulated in the QualityStandardforGroundwater (GB/T 14848—2017). The amount of residue added, the amount of water added and the extrusion stress have significant impacts on Ni in the leaching solution, but have little influence on Cr. The main PAHs detected in the leachate of permeated brick include naphthalene, acenaphthene, dihydroacenaphthene, fluorene and phenanthrene. The total concentration is in the range of 218.43—408.34μg/L. Acenaphthene is the main component in the leaching solution, and its relative mass distribution ratio is 59.80%—77.55%. This study can provide scientific basis for harmless treatment and resource utilization of oily sludge pyrolysis residue.

Key words: pyrolysis residue of oily sludge, permeable brick, leaching solution, heavy metal leaching, resource utilization

摘要：

热解残渣作为含油污泥热解的伴生物，存量日益增多，严重威胁生态环境。含油污泥热解残渣的成分与黏土矿物类似，为此，利用热解残渣代替黏土制备渗水砖，探究制备过程中残渣添加量、加水量和挤压应力对渗水砖抗压强度和透水性能的影响以及对渗水砖浸出液中重金属和多环芳烃（PAHs）浓度的影响。分析结果表明，残渣添加量、加水量和挤压应力对渗水砖的抗压强度和透水性能有较大影响，当残渣添加量为15%、加水量为13%（以上均为质量分数）、挤压应力为30MPa时，渗水砖的物理性能最佳。此时，抗压强度为32.20MPa，达到Cc30等级标准；透水系数为1.80×10^-2cm/s，高于《透水砖》（JC/T 945—2005）中所规定的1.00×10^-2cm/s。重金属和PAHs浸出实验结果表明，渗水砖浸出液中检出的金属包括Cr、Pb、Cu、Ni和Zn，且Cr、Cu和Zn的浓度均低于《地表水环境质量标准》（GB 3838—2002）中所规定的Ⅱ类标准限值和《地下水质量标准》（GB/T 14848—2017）中所规定的Ⅲ类标准限值。残渣添加量、加水量和挤压应力对浸出液中Ni的影响较大，而对Cr的影响较小。渗水砖浸出液中主要检测出萘、苊、二氢苊、芴和菲这5种PAHs，总浓度范围为218.43～408.34μg/L。其中，苊是浸出液中的主要成分，其相对质量分布比例为59.80%~77.55%。本研究可为含油污泥热解残渣的无害化处理和资源化利用提供科学依据。

关键词: 油泥热解残渣, 渗水砖, 浸出液, 重金属浸出, 资源化

CLC Number:

TU992.3

QUAN Cui, GAO Ningbo, ZHANG Guangtao, SUO Haojie. Leaching characteristics of heavy metals and polycyclic aromatic hydrocarbons from permeable bricks prepared by pyrolysis residue of oily sludge[J]. Chemical Industry and Engineering Progress, 2024, 43(9): 5226-5233.

全翠, 高宁博, 张广涛, 索浩杰. 含油污泥热解残渣制备渗水砖的重金属和多环芳烃浸出特性[J]. 化工进展, 2024, 43(9): 5226-5233.

Figures/Tables 14

References 13

1	LI Jiantao, ZHENG Fa, LI Qiushi, et al. Effects of inherent minerals on oily sludge pyrolysis: Kinetics, products, and secondary pollutants[J]. Chemical Engineering Journal, 2022, 431: 133218.
2	LIU Yang, YU Hejie, JIANG Zhihui, et al. Microwave pyrolysis of oily sludge under different control modes[J]. Journal of Hazardous Materials, 2021, 416: 125887.
3	GAO Ningbo, JIA Xiangyu, GAO Guanqun, et al. Modeling and simulation of coupled pyrolysis and gasification of oily sludge in a rotary kiln[J]. Fuel, 2020, 279: 118152.
4	BAO Diandian, LI Zhengwen, LIU Xiang, et al. Biochar derived from pyrolysis of oily sludge waste: Structural characteristics and electrochemical properties[J]. Journal of Environmental Management, 2020, 268: 110734.
5	韩磊. 含油污泥共热解残渣吸附剂的制备及性能研究[D]. 西安: 西安石油大学, 2022.
	HAN Lei. Preparation and Properties of adsorbent for oily sludge co-pyrolysis residue [D]. Xi’an: Xi’an Shiyou University, 2022.
6	曹蕊, 韩冬云, 朱涛, 等. 含油污泥热解残渣特性及其资源化利用[J]. 化工环保, 2023, 43(3): 353-358.
	CAO Rui, HAN Dongyun, ZHU Tao, et al. Characteristics and resource utilization of pyrolysis residue from oily sludge[J]. Environmental Protection of Chemical Industry, 2023, 43(3): 353-358.
7	尚贞晓, 赵庚, 马艳飞. 含油污泥催化热解及残渣资源化利用实验研究[J]. 石油与天然气化工, 2021, 50(6): 115-119.
	SHANG Zhenxiao, ZHAO Geng, MA Yanfei. Experimental study on catalytic pyrolysis of oily sludge and recycling of the residue[J]. Chemical Engineering of Oil and Gas, 2021, 50(6): 115-119.
8	李金灵, 张甜甜, 鱼涛, 等. 含油污泥热解残渣的制备及吸附性能综合性教学实验设计[J]. 实验技术与管理, 2021, 38(9): 187-190.
	LI Jinling, ZHANG Tiantian, YU Tao, et al. Comprehensive experimental design of preparation and adsorption of oily sludge pyrolysis residue[J]. Experimental Technology and Management, 2021, 38(9): 187-190.
9	高昌胜, 魏茂, 蒋文广, 等. 基于含油污泥热解残渣的路基材料制备与性能评价[J]. 硅酸盐通报, 2019, 38(6): 1895-1900.
	GAO Changsheng, WEI Mao, JIANG Wenguang, et al. Preparation and performance evaluation of roadbed materials based on pyrolysis residue of oily sludge[J]. Bulletin of the Chinese Ceramic Society, 2019, 38(6): 1895-1900.
10	王晓东, 李玉善, 田敬. 含油污泥间接热解吸处理后的再利用[J]. 油气田环境保护, 2015, 25(6): 46-49.
	WANG Xiaodong, LI Yushan, TIAN Jing. Reuse of oily sludge after indirect thermal desorption treatment[J]. Environmental Protection of Oil & Gas Fields, 2015, 25(6): 46-49.
11	全翠, 张广涛, 许毓, 等. 污泥热解残渣中重金属形态分布的研究进展[J]. 化工学报, 2022, 73(1): 134-143.
	QUAN Cui, ZHANG Guangtao, XU Yu, et al. Recent advances on the speciation distribution of heavy metals in sludge pyrolysis residue[J]. CIESC Journal, 2022, 73(1): 134-143.
12	QUAN Cui, ZHANG Guangtao, GAO Ningbo, et al. Behavior study of migration and transformation of heavy metals during oily sludge pyrolysis[J]. Energy & Fuels, 2022, 36(15): 8311-8322.
13	ZHANG Lixun, TANG Shengyin, HE Fangxin, et al. Highly efficient and selective capture of heavy metals by poly(acrylic acid) grafted chitosan and biochar composite for wastewater treatment[J]. Chemical Engineering Journal, 2019, 378: 122215.

元素	质量分数/%
元素	含油污泥	700℃残渣
Si	65.23	65.40
Al	7.89	7.72
Ca	7.44	7.40
Ba	6.07	5.99
Mg	4.56	4.53
S	3.27	3.49
Fe	1.78	1.81
K	1.51	1.55
Cl	0.91	0.76
P	0.81	0.82
其他	0.53	0.53

元素	质量分数/%
元素	含油污泥	700℃残渣
Si	65.23	65.40
Al	7.89	7.72
Ca	7.44	7.40
Ba	6.07	5.99
Mg	4.56	4.53
S	3.27	3.49
Fe	1.78	1.81
K	1.51	1.55
Cl	0.91	0.76
P	0.81	0.82
其他	0.53	0.53

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