Treatment of oily sludge through multiphase compound conditioning and demulsification separation process

doi:10.16085/j.issn.1000-6613.2022-0469

Abstract

Abstract:

Oily sludge widely exists in the petroleum exploration, petrochemical processing and application. Because of its high viscosity, complex and stable emulsification characteristics, the treatment of oily sludge is fairly difficult with low treatment efficiency. Aiming at the problem of low separation efficiency of traditional process, this study put forward the resourceful treatment of oily sludge through multiphase compound conditioning and demulsification separation process, based on the engineering application. Firstly, the different viscosity reduction methods of oily sludge was studied. It was found that the viscosity of oily sludge could be effectively reduced by multiphase composite method, owning to the control of the emulsification state, the dissolution of the heavy components and the destruction of its spatial structure. On this basis, the resourceful treatment of oily sludge was carried out by the combination of multiphase compound conditioning and demulsification, and the influence of conditioning and demulsification process on the treatment effect was studied respectively. The results showed that the addition of water could assist the conditioning process to reduce the viscosity effectively, help disperse oily sludge aggregates and promote the dissolution and mass transfer of heavy oil. The oil was dissolved and liberated from the solid surface by the solvent. Through the control of the emulsification state and the use of high-efficiency demulsifier, the efficient separation of oil, water and solid could be realized. When the solvent dosage was 130% and the water dosage was 30%, the system was in water-in-oil state. After adding 400mg/kg water-in-oil demulsifier TJU-3, the heavy oil recovery could reach to 92.9%, and the oil phase was clean. This study could provide reference for the large-scale resource recovery and treatment of oily sludge.

Key words: oily sludge, multiphase composite, viscosity reduction, demulsification, resourceful treatment

摘要：

含油污泥普遍存在于石油开采、加工及使用等过程中，因其高黏度、复杂稳定乳化特性导致处理难度大，处理效率低。针对传统工艺分离效率低的问题，本文基于工程应用的目标，提出油泥多相复合调质降黏破乳分离工艺，对油泥进行资源化分离。首先，对含油污泥进行了不同的降黏处理，分别通过添加正庚烷和水多相复合调质的方法，可以调控体系乳化状态，溶解重质组分，破坏其空间结构，有效降低含油污泥表观黏度。在此基础上，将调质降黏与破乳相耦合对含油污泥进行资源化回收处理，分别探究了调质过程和破乳过程对处理效果的影响。结果表明，加入水辅助调质降黏，可有效分散含油污泥团聚体，促进重油溶解与传质，正庚烷通过稀释降低油组分黏度，并从固体表面溶解剥离。通过对油泥乳化态的调控，协同使用高效破乳剂可实现油、水、固的高效分离。当溶剂用量130%，水用量30%时，体系为油包水状态，添加400mg/kg油包水型破乳剂TJU-3处理后，重油回收率可达92.86%，油相清洁。本研究可以为含油污泥大规模资源化回收处理提供参考。

关键词: 含油污泥, 多相复合, 降黏, 破乳, 资源化

CLC Number:

TE992

YANG Juanjuan, HE Lin, HE Changqing, LI Xingang, SUI Hong. Treatment of oily sludge through multiphase compound conditioning and demulsification separation process[J]. Chemical Industry and Engineering Progress, 2023, 42(2): 614-623.

杨娟娟, 何林, 贺常晴, 李鑫钢, 隋红. 含油污泥多相复合调质降黏破乳分离过程[J]. 化工进展, 2023, 42(2): 614-623.

Figures/Tables 15

References 30

1	HUI Kunlong, TANG Jun, LU Haojie, et al. Status and prospect of oil recovery from oily sludge: A review[J]. Arabian Journal of Chemistry, 2020, 13(8): 6523-6543.
2	JEREZ S, VENTURA M, MOLINA R, et al. Comprehensive characterization of an oily sludge from a petrol refinery: a step forward for its valorization within the circular economy strategy[J]. Journal of Environmental Management, 2021, 285: 112124.
3	HOCHBERG S Y, TANSEL B, LAHA S. Materials and energy recovery from oily sludges removed from crude oil storage tanks (tank bottoms): A review of technologies[J]. Journal of Environmental Management, 2022, 305: 114428.
4	DUAN Yihang, GAO Ningbo, SIPRA A T, et al. Characterization of heavy metals and oil components in the products of oily sludge after hydrothermal treatment[J]. Journal of Hazardous Materials, 2022, 424: 127293.
5	HU Guangji, LI Jianbing, ZENG Guangming. Recent development in the treatment of oily sludge from petroleum industry: A review[J]. Journal of Hazardous Materials, 2013, 261: 470-490.
6	KANWAL Q, LI Jinhui, ZENG Xianlai. Mapping recyclability of industrial waste for anthropogenic circularity: A circular economy approach[J]. ACS Sustainable Chemistry & Engineering, 2021, 9(35): 11927-11936.
7	DAL MAS F, ZENG Xianlai, HUANG Qifei, et al. Quantifying material flow of oily sludge in China and its implications[J]. Journal of Environmental Management, 2021, 287: 112115.
8	李文英, 李阳, 马艳飞, 等. 含油污泥资源化处理方法进展[J]. 化工进展, 2020, 39(10): 4191-4199.
	LI Wenying, LI Yang, MA Yanfei, et al. Progress of resource treatment methods for oily sludge[J]. Chemical Industry and Engineering Progress, 2020, 39(10): 4191-4199.
9	LI Jiantao, LIN Fawei, LI Kai, et al. A critical review on energy recovery and non-hazardous disposal of oily sludge from petroleum industry by pyrolysis[J]. Journal of Hazardous Materials, 2021, 406: 124706.
10	LI Gang, GUO Shuhai, HU Jinxuan. The influence of clay minerals and surfactants on hydrocarbon removal during the washing of petroleum-contaminated soil[J]. Chemical Engineering Journal, 2016, 286: 191-197.
11	FONTS I, GEA G, AZUARA M, et al. Sewage sludge pyrolysis for liquid production: A review[J]. Renewable and Sustainable Energy Reviews, 2012, 16(5): 2781-2805.
12	LIU Jia, ZHANG Yixuan, PENG Kaiming, et al. A review of the interfacial stability mechanism of aging oily sludge: heavy components, inorganic particles, and their synergism[J]. Journal of Hazardous Materials, 2021, 415: 125624.
13	ZADYMOVA N M, SKVORTSOVA Z N, TRASKIN V Y, et al. Heavy oil as an emulsion: Composition, structure, and rheological properties[J]. Colloid Journal, 2016, 78(6): 735-746.
14	LEE J, BABADAGLI T. Comprehensive review on heavy-oil emulsions: Colloid science and practical applications[J]. Chemical Engineering Science, 2020, 228: 115962.
15	HUANG Qunxing, MAO Feiyan, HAN Xu, et al. Migration of emulsified water droplets in petroleum sludge during centrifugation[J]. Energy & Fuels, 2014, 28(8): 4918-4924.
16	HUANG Qunxing, HAN Xu, MAO Feiyan, et al. A model for predicting solid particle behavior in petroleum sludge during centrifugation[J]. Fuel, 2014, 117: 95-102.
17	张辛铖, 何林,隋红, 等.重质油包水乳液破乳过程及降黏强化机制[J].化工进展, 2022, 41(7): 3534-3544.
	ZHANG Xincheng, HE Lin, SUI Hong, et al. Demulsification process and enhancement by viscosity reduction for water-in-heavy oil emulsions[J]. Chemical Industry and Engineering Progress, 2022, 41(7): 3534-3544.
18	ZHENG Xiaoyuan, YING Zhi, CUI Jie, et al. Simultaneous dewatering and recovering oil from high-viscosity oily sludge through the combination process of demulsification, viscosity reduction, and centrifugation[J]. Energy & Fuels, 2017, 31(12): 14401-14407.
19	LUQUE DE CASTRO M D, GARCÍA-AYUSO L E. Soxhlet extraction of solid materials: An outdated technique with A promising innovative future[J]. Analytica Chimica Acta, 1998, 369(1/2): 1-10.
20	Standard test method for separation of asphalt into four fractions: [S]. 2018-01-10.
21	ALOMAIR O A, ALMUSALLAM A S. Heavy crude oil viscosity reduction and the impact of asphaltene precipitation[J]. Energy & Fuels, 2013, 27(12): 7267-7276.
22	Sepideh MORTAZAVI-MANESH, SHAW John M. Effect of diluents on the rheological properties of Maya crude oil[J]. Energy & Fuels, 2016, 30(2): 766-772.
23	SOUAS F, SAFRI A, BENMOUNAH A. A review on the rheology of heavy crude oil for pipeline transportation[J]. Petroleum Research, 2021, 6(2): 116-136.
24	YANG Hongqiang, WANG Yanhong, DING Mingshan, et al. Water-assisted solvent extraction of bitumen from oil sands[J]. Industrial & Engineering Chemistry Research, 2012, 51(7): 3032-3038.
25	李美蓉, 于光松, 张丁涌, 等. 稠油W/O型乳状液转相特性研究[J]. 油田化学, 2017, 34(2): 335-339, 366.
	LI Meirong, YU Guangsong, ZHANG Dingyong, et al. Study on inversion characteristic for water-in-oil emulsion of heavy crude oil[J]. Oilfield Chemistry, 2017, 34(2): 335-339, 366.
26	PERAZZO A, PREZIOSI V, GUIDO S. Phase inversion emulsification: Current understanding and applications[J]. Advances in Colloid and Interface Science, 2015, 222: 581-599.
27	琚晨辉, 王燕民, 叶建东, 等. 颗粒粒度分布对高固相含量氧化铝浆料流变性能的影响[J]. 硅酸盐学报, 2006, 34(8): 985-991.
	JU Chenhui, WANG Yanmin, YE Jiandong, et al. Effect of particle size distribution on the rheological behavior of dense alumina suspensions[J]. Journal of the Chinese Ceramic Society, 2006, 34(8): 985-991.
28	ZAHABI A, GRAY M R, CZARNECKI J, et al. Flocculation of silica particles from a model oil solution: Effect of adsorbed asphaltenes[J]. Energy & Fuels, 2010, 24(6): 3616-3623.
29	齐茗, 林新宇, 黄作男, 等. 含油污泥调质破乳及减量化处理工艺[J]. 新疆石油天然气, 2015, 11(3): 91-96.
	QI Ming, LIN Xinyu, HUANG Zuonan, et al. The technology of oily sludge seasoning demulsification and minimization treatment[J]. Xinjiang Oil & Gas, 2015, 11(3): 91-96.
30	KANG Wanli, JING Guolin, ZHANG Hongyan, et al. Influence of demulsifier on interfacial film between oil and water[J]. Colloids and Surfaces A-Physicochemical and Engineering Aspects, 2006, 272(1/2): 27-31.

油泥种类	三相组成/%			干基含油率/%	油相四组分/%
油泥种类	含油率	含固率	含水率	干基含油率/%	饱和分	芳香分	胶质	沥青质
水洗粗油泥	35.71	13.39	50.90	72.73	30.42	27.59	30.00	11.99
落地油泥	14.74	57.98	27.28	20.57	47.4	28.37	18.77	5.46

油泥种类	三相组成/%			干基含油率/%	油相四组分/%
油泥种类	含油率	含固率	含水率	干基含油率/%	饱和分	芳香分	胶质	沥青质
水洗粗油泥	35.71	13.39	50.90	72.73	30.42	27.59	30.00	11.99
落地油泥	14.74	57.98	27.28	20.57	47.4	28.37	18.77	5.46

项目	一级处理结果	二级处理结果	一级水相回用的二级结果
残渣含油率/%	11.62	5.19	4.27
油相含固率/%	0.23	无明显固体	无明显固体
油相含水率/%	0.026	0.024	0.018

项目	一级处理结果	二级处理结果	一级水相回用的二级结果
残渣含油率/%	11.62	5.19	4.27
油相含固率/%	0.23	无明显固体	无明显固体
油相含水率/%	0.026	0.024	0.018

[1]	WU Ya, ZHAO Dan, FANG Rongmiao, LI Jingyao, CHANG Nana, DU Chunbao, WANG Wenzhen, SHI Jun. Research progress on highly efficient demulsifiers for complex crude oil emulsions and their applications [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4398-4413.
[2]	YANG Ziyu, ZHU Ling, WANG Wenlong, YU Chaofan, SANG Yimin. Research and application progress of smoldering combustion technology for oily sludge [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3760-3769.
[3]	DUAN Yihang, GAO Ningbo, QUAN Cui. Effect of hydrothermal treatment on pyrolysis characteristics and kinetics of oily sludge [J]. Chemical Industry and Engineering Progress, 2023, 42(2): 603-613.
[4]	YANG Zhuangzhuang, LIU Yongjun, LIU Xingshe, LIU Zhe, YANG Lu, ZHANG Aining. Coalescence separation of oily sludge and removal effect of organic substances from coal chemical wastewater [J]. Chemical Industry and Engineering Progress, 2023, 42(1): 538-545.
[5]	LI Songtao, ZHAO Jin, ZHANG Lifeng. Preparation of hyperbranched poly(amido amine) and its application to demulsification of oil-in-water emulsions [J]. Chemical Industry and Engineering Progress, 2023, 42(1): 401-408.
[6]	ZHANG Hua, LIU Guangquan, ZHANG Xiaofei, LUO Zhen. Stability analysis and demulsification treatment for desalter effluent [J]. Chemical Industry and Engineering Progress, 2022, 41(9): 5047-5054.
[7]	JIANG Huayi, HU Juan, QI Hongyuan, YOU Yanzhen, WANG Yulong, WU Zhe. Effect of magnetic nanoparticles type and mass concentration on microwave pyrolysis of oily sludge [J]. Chemical Industry and Engineering Progress, 2022, 41(7): 3908-3914.
[8]	ZHANG Xincheng, HE Lin, SUI Hong, LI Xingang. Demulsification process and enhancement by viscosity reduction for water-in-heavy oil emulsions [J]. Chemical Industry and Engineering Progress, 2022, 41(7): 3534-3544.
[9]	JIA Wenlong, SONG Shuoshuo, LI Changjun, WU Xia, YANG Fan, ZHANG Yuanrui. Progress of oily sludge extraction by supercritical CO₂ [J]. Chemical Industry and Engineering Progress, 2022, 41(12): 6573-6585.
[10]	WANG Shuai, ZHAO Jinzhu, WANG Rongyuan, CUI Kaixiang, JING Jiaqiang. New ideas of heavy oil flow drag reduction by emulsification and wetting coupling action [J]. Chemical Industry and Engineering Progress, 2021, 40(S2): 126-139.
[11]	ZHANG Lifeng, ZHAN Ningning, QIN Lijuan, ZHAO Xinxing, ZHOU Lishan, TENG Houkai, FANG Wenjun. Methacrylated hyperbranched polyglycerol demulsifier for O/W emulsion [J]. Chemical Industry and Engineering Progress, 2021, 40(6): 3434-3443.
[12]	BAO Qinghua, HUANG Lixin, XIU Jianlong, YU Li, CUI Qingfeng, MA Yuandong, YI Lina. Development in the biological treatment of oily sludge in oil and gas fields [J]. Chemical Industry and Engineering Progress, 2021, 40(5): 2762-2773.
[13]	FENG Yangyang, ZHAO Zhongcong, YANG Wenbo, HU Linqi, ZHANG Wenda, SHE Yuehui. Microbial natural synthetic metal nanoparticles and the application in heavy oil catalytic viscosity reduction [J]. Chemical Industry and Engineering Progress, 2021, 40(4): 2215-2226.
[14]	YU Yang, LIU Qi, PENG Bo, LYU Jing. A review of the biodegradation of asphaltene in heavy oil [J]. Chemical Industry and Engineering Progress, 2021, 40(3): 1574-1585.
[15]	ZHANG Nan, WANG Yujing, LIU Shejiang, ZHANG Kai. Progress and prospects on the thermochemical cleaning of oily sludge [J]. Chemical Industry and Engineering Progress, 2021, 40(3): 1276-1283.