References

  1. J.Q. Liang, W. Luo, Q. Li, Y.X. Wang, H.L. Su, Application of centrifugal dehydration technology in aging oil treatment, Water Wastewater Eng., 50 (2014) 261–263.
  2. D. Wu, S.C. Wang, X.C. Meng, F.L. Zhao, Q.S. Wang, H.C. Liang, Thermo-chemical demulsification/dehydration of high water cut crude oil produced from ASP flooding reservoir in Daqing, Oilfield Chem., 19 (2002) 54–58.
  3. H.T. Wu, L. Lai, J. Lui, W. Chen, P. Mei, Influence of some oilfield chemicals on demulsification/dehydration of crude oils and demulsifier selection, Oilfield Chem., 26 (2009) 286–289.
  4. S.G. Cheng, S.G. Lui, Preliminary inquire into waste oil disposal in Jianghan oil region, J. Jianghan Pet. Workers Univ., 21 (2008) 57–60.
  5. Y.J. Li, S. Sun, Application of new technology for aging oil dehydration, Drill. Prod. Technol., 31 (2008) 139–141.
  6. Z.P. Ren, X.L. Wang, Z. Xie, Formation of W/O emulsion during Changqing crude oil dehydration and its characteristics, Oil Gas Storage Transport., 11 (2013) 1209–1212.
  7. Y.M. Pan, H.Y. Wang, X.-J. Wang, Adaptability for handling aging oil by using cyclone separating technique, J. Oil Gas Technol., 27 (2005) 414–416.
  8. X.P. Bao, L.M. Guo, Discussion on formation mechanism and treatment method of aging oil, Hangzhou Chem. Ind., 38 (2008) 7–9,16.
  9. F. Nezhdbahadori, M.A. Abdoli, M. Baghdadi, F. Ghazban, A comparative study on the efficiency of polar and non-polar solvents in oil sludge recovery using solvent extraction, Environ. Monit. Assess., 190 (2018) 1–9, doi: 10.1007/s10661-018-6748-6.
  10. X.G. Liu, Analysis on the causes of formation of oilfield aging oil and discussion on treatment technology, Chem. Enterp. Manage., 18 (2015) 19.
  11. Q. Xue, J. Wang, Technology for recovery of aging oil, Inner Mongolia Petrochem., 2 (2008) 19–21.
  12. J.Y. Feng, H.Y. Tang, Research progress of microbial treatment of aging oil, Contemp. Chem. Ind., 47 (2018) 1691–1694.
  13. Q.Y. Hao, Technology for recovery of aging oil and application in Daqing oilfield, Chem. Ind., 27 (2009) 32–35.
  14. Z. Jing, Study on comprehensive dewatering technology of heavy oil and super heavy oil, Oil-Gasfield Surf. Eng., 29 (2010) 29–30.
  15. W. Yang, X.Y. Fu, Application of ultrasonic demulsification dehydration technology in Tahe oilfield, Nat. Gas Oil, 32 (2014) 23–24+31+5.
  16. Z.J. Wang, S.M. Gu, Z. Long, Research on the static experiment of super heavy crude oil demulsification and dehydration using ultrasonic wave and audible sound wave at high temperatures, Ultrason. Sonochem., 40 (2018) 1014–1020.
  17. M.S. Mullakaev, G.I. Volkova, O.M. Gradov, Effect of ultrasound on the viscosity-temperature properties of crude oils of various compositions, Theor. Found. Chem. Eng., 49 (2015) 287–296.
  18. M.A. Ershov, D.A. Baranov, M.S. Mullakaev, V.O. Abramov, Reducing viscosity of paraffinic oils in ultrasonic field, Chem. Pet. Eng., 47 (2011) 457–461.
  19. W.H. Zhong, A.X. Wang, C.F. Zhang, X.P. Lv, P.F. Han, Application of ultrasound in the viscosity reduction of vacuum residuum, Chem. Ind. Eng. Prog., 28 (2009) 1896–1900.
  20. G.J. Sha, Experimental study on the viscosity reduction by ultrasonic wave for aged oil, Oil Prod. Eng., 2 (2019) 71–75+88.
  21. J.X. Qiao, W.P. Song, X.Y. Yu, H.Q. Zhang, L.Q. Li, W.Y. Wang, Experimental study on aging oil viscosity reduction caused by ultrasound, J. Harbin Univ. Sci. Technol., 24 (2019) 42–46.
  22. M.Y. Yi, J. Huang, L.F. Wang, Research on crude oil demulsification using the combined method of ultrasound and chemical demulsifier, J. Chem., 2017 (2017) 1–7.
  23. L.L. Zheng, Analysis on the applicability of ultrasonic demulsification technology, Chem. Eng. Equip., 1 (2017) 71–72.
  24. X.K. Sun, Y.Q. Xia, Z.S. Yin, D.S. Mou, S.L. Xia, D.X. Jin, Aging Oil and Sludge Treatment Method and Device, Chinese Patent: CN 104445848A, 2015.
  25. X.Y. Fu, Research on Ultrasonic Dehydration Technology of Acid Heavy Oil in TaHe Oilfield, Southwest Petroleum University, Chengdu, 2013.
  26. P.F. Han, N. Xu, X.P. Lv, Y.R. Wang, Applying ultrasound to demulsification of dirty oil for water removal, J. Nanjing Univ. Technol., 25 (2003) 73–75.
  27. X.F. Fu, Influencing factors of ultrasonic crude oil demulsification on offshore platform, Chem. Eng. Equip., 3 (2013) 98–99.
  28. W.Q. Gao, D.M. Gao, F.L. Wei, Influencing factors of ultrasonic crude oil demulsification, Inner Mongolia Petrochem. Ind., 23 (2008) 36–37.
  29. X. Yin, G.X. Ye, X.P. Lu, P.F. Han, Demulsifying and dewatering of waste oil by ultrasound, J. Nanjing Univ. Technol., 31 (2009) 69–73.
  30. J. Ao, H.J. Li, X.L. Wang, Diagnosis and treatment of aging oil in settling tank, Oil-Gasfield Surf. Eng., 32 (2013) 26–27.
  31. K. Tong, Q.H. Song, G.Q. Liu, Research progresses on aging oil treatment techniques, Environ. Prot. Chem. Ind., 38 (2018) 629–634.
  32. M. Song, The stability analysis and synthetical treatments study of aging oil, China University of Petroleum (EastChina), Qingdao, 2014.
  33. W. Xie, R. Li, X.P. Lu, Pulsed ultrasound assisted dehydration of waste oil, Ultrason. Sonochem., 26 (2015) 136–141.
  34. X. Gong, J. Zhang, J. Tang, X.G. Zang, S.C. Lu, Study on electric demulsification method, Energy Environ., 2 (2015) 16–17.
  35. Y. Lu, Research progress in physical demulsification of crude oil, Contemp. Chem. Ind., 45 (2016) 946–948.
  36. H. Yang, X. Huang, Z.Z. Lin, Z.J. Shen, Research progress of water-in-oil crude oil emulsion demulsification technology, Appl. Chem., 12 (2018) 2734–2738+2743.
  37. W.L. Kang, K.B. Zhang, S.R. Liu, D.Q. Cao, H.M. Fan, Demulsification efficiency of high-frequency pulsed AC electrical fields on water-in-oil emulsions, Oil Gas Storage Transport., 30 (2011) 771–774.
  38. J.S. Eow, M. Ghadirt, A.O. Sharif, T.J. Williams, Electrostatic enhancement of coalescence of water droplets in oil: a review of the current understanding, Chem. Eng. J., 84 (2001) 173–192.
  39. S.H. Mousavi, M. Ghadiri, M. Buckley, Electro-coalescence of water drops in oils under pulsatile electric fields, Chem. Eng. Sci., 120 (2014) 130–142.
  40. Y. Ding, J.Q. Chen, J.Y. Chang, S.T. Huang, Q.D. Chu, Research onto the electrostatic coalescing characteristics of water-inoil emulsions under high-voltage and high-frequency pulsed alternating current electric field, J. Chem. Eng. Chin. Univ., 25 (2011) 775–780.
  41. W.W. Shen, R.F. Li, J.Q. Chen, R.F. Li, S.T. Huang, S. Li, Q. Ma, Research onto the electrostatic coalescing characteristics of water-in-oil emulsions under high-voltage and high-frequency pulsed alternating current electric field, J. Chem. Eng. Chin. Univ., 28 (2014) 812–817.
  42. W.W. Shen, J.Q. Chen, C.Y. Hu, S.T. Huang, S. Zhang, J. Hu, Development and application of dual frequency electric field technology for crude oil dehydration (desalting), China Pet. Mach., 42 (2014) 56–60.
  43. Z.H. Pan, J.Q. Chen, L. Zhang, F. Li, C.S. Wang, R. Xie, P. Li, Research on dehydration of aging oil from Liuhua oilfield by high frequency and high voltage pulse electric field, Chin. J. Process Eng., 15 (2015) 969–975.
  44. J.Q. Chen, S.T. Huang, W.W. Shen, Z.H. Pan, L. Zhang, B.S. Zhang, Experiment on demulsification characteristics of water-in-oil emulsions in high-frequency electric field, Oil Gas Storage Transport., 36 (2017) 694–701.
  45. W.J. Li, The Research on Mechanism and Device of Aged Oil Demulsification under High Voltage and High Frequency Pulsed AC Electric Field, Beijing Institute of Petrochemical Technology, Beijing, 2018.
  46. Z.H. Wang, X.P. Le, Y.G. Feng, Z.W. Hu, Dehydration of aging oil by an electrochemical method, Chem. Technol. Fuels Oils, 50 (2014) 262–268.
  47. Y.X. Wu, J.Y. Xu, Oil and water separation technology, Adv. Mech., 45 (2015) 179–216.
  48. M.H. Jiang, Research and application of hydrocyclonic separation technology, J. Daqing Pet. Inst., 34 (2010) 101–109+171.
  49. J.H. Duan, S.B. Huang, C. Gao, A. Chen, Q.S. Huang, Influence of slit structure in hydrocyclone conical section on solid–liquid separation performance, J. Chem. Ind. Eng. (China), 70 (2019) 1823–1831.
  50. L.X. Zhao, M.H. Jiang, D.Z. Sun, Recent progress of hydrocyclone separation research, Chem. Ind. Eng. Prog., 24 (2005) 1118–1123.
  51. F.Y. He, Y. Sun, X.L. Wang, Application of hydrocyclone in aging oil treatment, J. Daqing Pet. Inst., 32 (2008) 52–55.
  52. X.L. Wang, Application of Aging Oil Treatment by Using Hydrocyclone, Daqing Petroleum Institute, Daqing, 2006.
  53. M.H. Jiang, L.X. Zhao, F. Li, J. He, Research on the inlet patterns of liquid–liquid hydrocyclone, Oil Field Equip., 27 (1998) 3–6.
  54. F. Li, M.H. Jiang, L.X. Zhao, Tube style design of the three cubed curve liquid–liquid hydrocyclones, Chem. Eng. Mach., 32 (2005) 82–84.
  55. J. He, M.H. Jiang, H. Song, L.X. Zhao, A study of natural parameters of a liquid–liquid separating hydrocyclon, Acta Petrolei Sinica, 17 (1996) 84–87.
  56. J.G. Wang, Y.H. Zhang, Z.Y. Bai, C. Huang, H.L. Wang, Effects of inlet size on separation flow field inside hydrocyclone, J. Chem. Ind. Eng. (China), 65 (2014) 205–212.
  57. Z. Wang, L.X. Zhao, Study on flow field characteristics and separation characteristics of liquid–liquid hydrocyclone (6) – influence of structural parameters on separation characteristics, Chem. Equip. Technol., 21 (2000) 14–16.
  58. M.H. Jiang, L.X. Zhao, Z.C. Wang, Effects of Geometric and Operating Parameters on Separation Performance for Hydrocyclones, Proceedings of the 12th International Conference on Offshore and Polar Engineering, ISOPE-2002, Kitakyushu, 2002, pp. 102–106.
  59. Y. Zhang, Z.H. Cao, S. Zhang, L. Xing, Influence of separation chamber structure on separation performance of downhole hydrocyclone, China Pet. Mach., 47 (2019) 98–104.
  60. L.X. Zhao, M. Zhang, W.Q. Liu, L.J. Zou, Flow field analysis and structural optimization of conetyped deoiling hydrocyclones, Chem. Eng. Mach., 38 (2011) 202–205.
  61. D. Zhang, Y. Chen, Effect of the cone angle on flow field and separation performance of solid–liquid hydrocyclones, Fluid Mach., 37 (2009) 11–16.
  62. A.S. Liu, M.H. Jiang, J. He, L.X. Zhao, Pressure drop ratio— an important performance parameter of liquid–liquid cyclone separation, Oil Field Equip., 26 (1997) 27–29+21.
  63. F. Li, G. Liu, Separation characteristics study on hydrocyclonefilters, Chem. Eng. Mach., 35 (2008) 7–9.
  64. X.M. Liu, M.H. Jiang, Testing research of pressure drop in static de-oiling hydrocyclone, Fluid Mach., 32 (2004) 4–6,53.
  65. J.Y. Tian, L. Ni, T. Song, J. Olson, J.N. Zhao, An overview of operating parameters and conditions in hydrocyclones for enhanced separations, Sep. Purif. Technol., 206 (2018) 268–285.
  66. T.Q. Fu, M.Y. Zhang, Heavy Oil Aging Oil Dehydration Device, Chinese Patent: CN 04589088 U, 2015.
  67. Y.H. Gao, R. Mo, H.B. Liang, G.D. Gu, Study on physical properties of aging oil and dehydration technology, Sci. Technol. Chem. Ind., 23 (2015) 22–25.
  68. R. Mo, Oilfield Aging Oil Dehydration Process Technology Research, Northeast Petroleum University, Daqing, 2015.
  69. H.T. Chen, H.B. Liang, R. Mo, S. Zhu, Z.P. Yang, Bumping mechanism of aging oils, J. Chem. Ind. Eng., 66 (2015) 4823–4828.
  70. Y. Chen, R. Mo, F.Y. Kong, X.N. Zhang, Key technologies and processes of aging oil distillation and dehydration, Chem. Eng. Mach., 43 (2016) 38–42.
  71. H.B. Liang, Y.N. Zhuo, H.T. Chen, Q. Liu, Temperature precision control technology for aging oil distillation unit, Acta Petrolei Sinica (Petroleum Processing Section), 31 (2015) 991–995.
  72. H.B. Liang, H.T. Chen, Y. Chen, X.Y. Wang, Design of atmospheric distillation dehydration unit for aging crude oil with high water content, Chem. Eng. Mach., 41 (2014) 442–445+451.
  73. H.B. Liang, H.T. Chen, Y. Chen, Y.Z. Liang, Dewatering device for aging oil deep distillation, Control Instrum. Chem. Ind., 41 (2014) 915–918.
  74. H.T. Chen, Design of Aged Oil Dehydration Heat Exchanger and Research on Device Experiment, Northeast Petroleum University, Daqing, 2018.
  75. Y.L. Wang, H.B. Liang, B.J. Wang, Z.H. Ma, Z.B. Wang, Y. Chen, H.T. Chen, A Method for Aging Oil Dehydration Device and Method, Chinese Patent: CN 109135813 B, 2020.
  76. G.G. Huang, Brief Analysis of Aging Oil Treatment Technology, Yunnan Chemical Technology, 2019, p. 46.
  77. Z. Zuo, Study on Treatment of Aging Oil by Biochemical Demulsifier, China University of Petroleum (EastChina), Qingdao, 2011.
  78. Y.R. Fu, L.X. Fu, Q. Fu, Z.M. Wu, X.N. Liu, Study on biochemical demulsifier used treatment crude containing aging oil, Fine Specialty Chem., 18 (2010) 44–46.
  79. X.J. Meng, D.F. Chen, X.P. Cao, H.X. Xu, J. Chen, J. Zhao, Progress on aged oil treatment by biological technology, Chem. Ind. Eng. Prog., 35 (2016) 2406–2411.
  80. H.D. Bai, Analysis on biological demulsification treatment of aging oil, Sci. Technol. Dev., 2 (2010) 7.
  81. Y. Wen, H. Cheng, L-J. Lu, J. Liu, Y. Feng, W. Guan, Q. Zhou, X.-F. Huang, Analysis of biological demulsification process of water-in-oil emulsion by Alcaligenes sp. S-XJ-1, Bioresour. Technol., 101 (2010) 8315–8322.
  82. X.-F. Huang, Q.-W. Zhu, C.-L. Wang, S. Yang, L.-J. Lu, J. Liu, Demulsification of water-in-oil emulsions by a demulsifying Alcaligenes sp. strain growth on n-alkane, Environ. Eng. Manage. J. (EEMJ), 16 (2017) 1473–1480.
  83. Y.Y. Zhang, J. Liu, X.-F. Huang, L.J. Lu, K.M. Peng, Chemically modified surface functional groups of Alcaligenes sp. S-XJ-1 to enhance its demulsifying capability, Appl. Microbiol. Biotechnol., 101 (2017) 3839–3848.
  84. Q.H. Cai, Z.W. Zhu, B. Chen, B.Y. Zhang, Oil-in-water emulsion breaking marine bacteria for demulsifying oily wastewater, Water Res., 149 (2019) 292–301.
  85. H.Z. Zhang, Z.B. Liu, Z. Sun, Experimental study on vacuum film dehydration of aging oil, Ind. Water Treat., 39 (2019) 93–96.
  86. X.M. Zhang, New technology of oil-water separation and its application practice, Metal Miner., 7 (2001) 29–31.
  87. C. Zhang, K.P. Zhou, Numerical simulation of dehydration with negative pressure, Metal Miner., 2 (2012) 1–4+11.
  88. Q. Gao, L.S. Wang, X.C. Sun, Study on technological parameters of negative pressure dehydration, China Pet. Chem. Standard Qual., 34 (2014) 267.
  89. B.B. Li, A Treatment Process for Aged Oily Oil, Chinese Patent: CN 105950212 A, 2016.
  90. J.Q. Liu, X.C. Wei, Q. Li, J. Peng, Technology of negative pressure dehydration of aging oil, Oil-Gasfield Surf. Eng., 30 (2011) 61–63.
  91. W. Liu, J.Q. Chen, The dehydration effect of microwave radiation on water-bearing crude oil of complex aging oil, Oil- Gasfield Surf. Eng., 31 (2012) 20–21.
  92. B. Zhang, Study on Microwave-Assisted Thermochemical Demulsification and Dehydration of Aging Oil in Liuhua Oilfield, Southwest Petroleum University, Chengdu, 2016.
  93. Y.M. Ma, C. Zhao, W. Zhang, J.W. Zhang, H.C. Wang, H.K. Teng, A.M. Chen, J.X. Yu, L.S. Zhou, G.Y. Yao, A Method for Microwave Treatment of Aged Oil, Chinese Patent: CN 109628137 A, 2019.
  94. K. Tong, Q.H. Song, Y.X. Xie, D. Wang, W. Ren, W. Zeng, M.D. Zhang, J.W. Sun, X.H. Liu, Z. Zhang, A Method for Dehydration and Refining of Aging Oil and its System, Chinese Patent: CN 108251153 A, 2018.
  95. C. Ogwah, M.O. Eyankware, Investigation of hydrogeochemical processes in groundwater resources located around abandoned Okpara coal mine, Enugu Se. Nigeria, J. Clean WAS, 4 (2020) 12–16.
  96. X.F. Li, L.L. Guo, B.J. Shen, Advance in catalytic pyrolysis technology and its catalyst, Chem. Ind. Eng. Prog., 36 (2017) 203–210.
  97. M.C. Ning, F.M. Fan, P. Lu, F. Bai, C. Hua, Y.H. Wang, Technology for utilization of naphtha resources as by-product of heavy oil catalytic cracking, Nat. Gas Chem. Ind., 44 (2019) 93–97+118.
  98. S. Ibrahim, J.I. Magaji, A.T. Ogah, K. Karagama, Evaluation and impact of climatic variability on Guinea Corn (Sorghum bicolor) in selected state in Nigeria, Environ. Ecosyst. Sci., 4 (2020) 10–14.
  99. J.C. Zhang, Catalytic cracking process and its application, Nanlian Sci. Technol., 5 (1998) 28–33.
  100. S.J. Luo, J. Yan, L. Wang, C.H. Liu, Catalytic pyrolysis process and its application prospect, Pet. Plann. Eng., 21 (2010) 14–16+50.
  101. Z.T. Li, F.K. Jiang, C.G. Xie, Y.H. Xu, DCC technology and its commercial experience, Pet. Petrochem. Today, 9 (2001) 31–35.
  102. H. Janvier, M. Blessing, Performance evaluation of irrigation schemes in Rugeramigozi marshland, Rwanda, Water Conserv. Manage., 4 (2020) 15–19.
  103. B.K. Debnath, U.K. Saha, N. Sahoo, A comprehensive review on the application of emulsions as an alternative fuel for diesel engines, Renewable Sustainable Energy Rev., 42 (2015) 196–211.
  104. N. Wan, Refining Process of Aging Oil and Fuel Products and its Application in Diesel Tractors, Heilongjiang Bayi Agricultural University, Daqing, 2016.