References
  1. Fan YV, Lee CT, Lim JS, Klemeš JJ, Le PTK. Cross-disciplinary Approaches Towards Smart, Resilient and Sustainable Circular Economy. Journal of Cleaner Production. 2019;232: 1482-1491.
  2. El-Halwagi MM, Manousiouthakis V. Synthesis of Mass Exchange Networks. AIChE Journal. 1989;35(8):1233-1244
  3. Linnhoff B, Townsend DW, Boland D, Thomas BEA, Guy AR, Marsland RH. A user guide on process integration for the efficient use of energy (2nd ed). Rugby, UK: IChemE. 1982.
  4. Wang YP, Smith R. Wastewater minimisation. Chemical Engineering Science.1994; 49:981–1006.
  5. Olesen SG, Polley GT. A Simple Methodology for the Design of Water Networks Handling Single Contaminants. Chemical Engineering Research and Design. 1997; 75:420–426.
  6. Hallale N. A new graphical targeting method for water minimisation. Advances in Environmental Research. 2002;6:377–390.
  7. Gomes JFS, Queiroz EM, Pessoa FLP. Design procedure for water/wastewater minimisation: single contaminant. Journal of Cleaner Production. 2007;15:474–485.
  8. El-Halwagi MM (Ed.). Synthesis of mass exchange networks: A graphical approach, In: Process Systems Engineering, Process Integration. Massachusetts: Academic Press, 2006:87–136.
  9. El-Halwagi MM, Gabriel F, Harell D. Rigorous Graphical Targeting for Resource Conservation via Material Recycle/Reuse Networks. Industrial & Engineering Chemistry Research. 2003; 42: 4319–4328.
  10. Foo DCY. State-of-the-Art Review of Pinch Analysis Techniques for Water Network Synthesis. Industrial & Engineering Chemistry Research. 2009;48:5125–5159.
  11. Klemeš JJ, Kravanja Z. Forty years of Heat Integration: Pinch Analysis (PA) and Mathematical Programming (MP). Current Opinion in Chemical Engineering. 2013; 2(4): 461–474.
  12. Klemeš JJ, Varbanov PS, Walmsley TG, Jia X. New directions in the implementation of Pinch Methodology (PM). Renewable and Sustainable Energy Reviews. 2018;98: 439–468.
  13. Alva-Argáez A, Vallianatos A, Kokossis A. A multi-contaminant transhipment model for mass exchange networks and wastewater minimisation problems. Computers & Chemical Engineering. 1999;23:1439–1453.
  14. Ulson de Souza AA, Forgiarini E, Brandão HL, Xavier MF, Pessoa FLP, Souza SMAGU. Application of Water Source Diagram (WSD) method for the reduction of water consumption in petroleum refineries. Resources, Conservation and Recycling. 2009;53(3):149-154.
  15. Karthick R, Kumaraprasad G, Sruti B. Hybrid optimisation approach for water allocation and mass exchange network. Resources, Conservation and Recycling. 2010;54(11):783-792.
  16. Gomes JFP, Mirre RC, Delgado BEPC, Queiroz EM, Pessoa FLP. Water sources diagram in multiple contaminant processes: maximum reuse. Industrial Engineering and Chemistry Research. 2013;53(4):1667-1677.
  17. Calixto EES, Francisco FS , Pessoa FLP, Queiroz EM. A Novel Approach to Predict Violations and to Define the Reference Contaminant and Operation in Water Using Networks. Computer Aided Chemical Engineering. 2015;37: 1901-1906.
  18. Francisco FS, Mirre RC, Calixto EES, Pessoa FLP, Queiroz EM. Water sources diagram method in systems with multiple contaminants in fixed flowrate and fixed load processes. 2018;172:3186-3200
  19. Calixto EES, Pessoa FLP, Mirre RC, Francisco FS ,Queiroz EM. Water Sources Diagram and Its Applications. 2020;8(3):313
  20. Castaño JA, Higuita JC. Using turbidity for designing water networks. Journal of Environmental Management. 2016;172:129–135.
  21. Mabitla SS, Majozi T. A hybrid method for synthesis of integrated water and regeneration networks with variable removal ratios. Journal of Environmental Management. 2019;231:666–678.
  22. Liu ZY, Yang Y, Wan LZ, Wang X, Hou KH. A heuristic design procedure for water-using networks with multiple contaminants. AIChE Journal. 2009;55: 374–382.
  23. Fan XY, Li YP, Liu ZY, Pan CH. A new design method for water-using networks of multiple contaminants with the concentration potential concepts. Chemical Engineering Science. 2012;73: 345–353.
  24. Li AH, Fan XY, Klemeš JJ, Liu ZY. Concentration potential concepts: Powerful tools for design of water-using networks with multiple contaminants. Journal of Cleaner Production. 2017;165: 254–261.
  25. Zhao HP, Yang Y, Liu ZY. Design of heat integrated water networks with multiple contaminants. Journal of Cleaner Production. 2019;211: 530–536.
  26. Wang YP, Smith R. Wastewater minimisation with flowrate constraints. Transactions of the Institute of Chemical Engineers. 1995;73: 889-904.
  27. Chin HH, Liew PY, Varbanov PS, Klemeš JJ. Pinch-based Targeting Methodology for Multi-Contaminant Material Recycle/Reuse. Chemical Engineering Science. 2020. DOI: 10.1016/j.ces.2020.116129
  28. Short M, Isafiade AJ, Biegler LT, Kravanja Z. Synthesis of mass exchanger networks in a two-step hybrid optimisation strategy. Chemical Engineering Science. 2018; 178:118-135.
  29. Oladosu WA, Wan ALwi SR, Manan ZA. A new algebraic tool for simultaneous targeting and design of a mass exchange network with stream splitting for sustainable environment. Journal of Cleaner Production. 2020;249: 119361.
  30. Yanwarizal, Oladosu WA, Wan Alwi SR, Manan ZA, Fraser D. A new graphical approach for simultaneous targeting and design of mass exchange networks. Computers & Chemical Engineering. 2020;142: 107061.
  31. Yang M, Feng X, Chu KH, Liu G. Graphical method for identifying the optimal purification process of hydrogen systems. Energy. 2014;73: 829-837.
  32. Teles J, Castro PM, Novais AQ. LP-based solution strategies for the optimal design of industrial water networks with multiple contaminants. Chemical Engineering Science. 2008;63(2): 376-394.
  33. Lovelady EM, El-Halwagi MM, Krishnagopalan GA. An integrated approach to the optimisation of water usage and discharge in pulp and paper plants. IJEP. 2007;29: 274.
  34. Dakwala M, Mohanty B, Bhargava R. A process integration approach to industrial water conservation: a case study for an Indian starch industry. Journal of Cleaner Production. 2009;17: 1654–1662.