References

  1. L. Shuhui, Y. Qiujuan, Papermaking industry clean production, environmental protection, recycling, Beijing, Chemical Industry Press, 2007.
  2. S. Park, S. Lee, J. Han, Effect of coagulation pretreatment on microfiltration of paper mill wastewater using electrospun membranes, Desal. Water Treat., 77 (2017) 83–88.
  3. C.M. Sheridan, K.G. Harding, A. Brink, The Fenton oxidation of biologically treated paper and pulp mill effluents: A performance and kinetic study, Process Safety Environ. Protect., 107 (2017) 206–215.
  4. K. Sudarshan, P. Kotteeswaran, Reuse the pulp and paper industry wastewater by using fashionable technology, Appl. Water Sci., 7(6) (2017) 3317–3322.
  5. B.R. Yadav, A. Garg, Hetero-catalytic hydrothermal oxidation of simulated pulping effluent: Effect of operating parameters and catalyst stability, Chemosphere, 191 (2017) 128–135.
  6. X.J. Zhou, N.Q. Ren, W.Q. Guo, A review on treatment methods of dye wastewater, CIESC J., 101 (2013) 23983–23992.
  7. J.X. Lv, Y. Cui, Treatment of reactive red X-3B dye wastewater with Cu-Fe inner electrolysis method, China Dyeing Finish., 7 (2015) 17–20.
  8. K. Yin, P.H. Rao, I. Lo, M.S.H. Mak, H.R. Dong, Lab-scale simulation of the fate and transport of nano zero-valent iron in subsurface environments: Aggregation, sedimentation and contaminant desorption, J. Hazard. Mater., 228 (2012) 118–125.
  9. X.B. Zhang, W. Yang, F.Y. Sun, W.Y. Dong, J. Dong, Degradation efficiency and mechanism of azo dye RR2 by a novel ozone aerated internal micro-electrolysis filter, J. Hazard. Mater., 276 (2014) 77–87.
  10. Z.P. Xu, G.Y. Song, J.H. Luo, G.R. Qing, J.Y. Liu, Mechanism of enhanced nitrate reduction via micro-electrolysis at the powdered zero-valent iron/activated carbon interface, J. Colloid Interf. Sci., 435 (2014) 21–25.
  11. J.J. Yang, X.J. Xu, G. Wang, R. Nie, X. Li, K.Y. Gao, Treatment of wastewater containing copper by coupling electrolysis with intensified micro-electrolysis, Chinese J. Nonferr. Metal, 23(10) (2013) 2936–2941.
  12. J. Wu, L.T. Pan, Y. Han, Advanced treatment of biologically pretreated coking wastewater by intensified zero-valent iron process (IZVI) combined with anaerobic filter and biological aerated filter (AF/BAF), J. Central South Univ., 22(10) (2015) 3781–3787.
  13. L.T. Pan, Y. Han, A novel anoxic-aerobic biofilter process using new composite packing material for the treatment of rural domestic wastewater, Water Sci. Technol., 73(10) (2016) 2486– 2492.
  14. C.Y. Zhang, Research of Advanced Treatment of Livestock Wastewater by Subsurface Flow Constructed Wetland. Master’s thesis. Zhengzhou University, 2012.
  15. L.M. Ma, Y.Y. Gu, K. Feng, Research on optimum coagulation conditions and pH variation of acidic chemical wastewater pretreated by catalyzed iron and coagulation process, Water Resour. Water Eng., 24(3) (2013) 50–53.
  16. L. Zhiyuan, Study on Fenton Oxidation-Coagulation Method of Biologically Treated Coal-chemical Engineering Wastewater. Master’s thesis. Harbin Institute of Technology, 2013.
  17. A.S. Lea, D.J. Gaspar, M.H. Engelhard, D.R. Baer. R.M, P.G. Tratnyek, Evidence for localization of reaction upon reduction of carbon tetrachloride by granular iron, Langmuir, 18(20) (2002) 7688–7693.
  18. O. Faix, Classification of lignins from different botanical origins by FT-IR spectroscopy, Holzforschung, 45S (1991) 21–27.
  19. S. Hanchang, C. Can, Study on the iron chip surface chemistry of iron chip process treating wastewater containing dyes, Environ. Chem., 23(1) (2004) 90–95.
  20. T.L. Johnson, W. Fish, P.G. Tratnyek, Y.A. Gorby, Degradation of carbon tetrachloride by iron metal: Complexation effects on the oxide surface, J. Contam. Hydrology, 29(4) (1998) 379– 398.
  21. X. Xiao, Treating pulping middle stage effluent by microelectrolysis method, Sci. Technol., 24(6) (2005) 102–105.