A rule-based design methodology for water networks with internal water mains

Chemical Engineering Research and Design

Volumn 85, Issue 4 A, 2007, Pages 431-444

  Ma, H ^a   Feng, X ^a   Cao, K ^a  

^a XI'AN JIAOTONG UNIVERSITY   (China)

Author keywords

Freshwater conservation and wastewater reduction; Heuristic rule; Internal water main; Water network

Indexed keywords

HEURISTIC PROGRAMMING; LOGIC PROGRAMMING; MATHEMATICAL MODELS; MATHEMATICAL PROGRAMMING; WATER PIPELINES; WATER RESOURCES; WATER SUPPLY;

INTERNAL WATER MAINS; WATER NETWORK; WATER SINK;

WATER DISTRIBUTION SYSTEMS;

HEURISTIC PROGRAMMING; LOGIC PROGRAMMING; MATHEMATICAL MODELS; MATHEMATICAL PROGRAMMING; WATER DISTRIBUTION SYSTEMS; WATER PIPELINES; WATER RESOURCES; WATER SUPPLY;

EID: 34247556566     PISSN: 02638762     EISSN: None     Source Type: Journal    
DOI: 10.1205/cherd06139     Document Type: Article

References (26)

1. Alva-Argaez, A.A., Kokossis, C. and Smith, R., 1998, Wastewater minimization of industrial system using an integrated approach, Comput Chem Eng, 22(Suppl): S741-S744.
2. Bagajewicz, M., Rivas, M. and Savelski, M., 1999, A new approach to the design of utilization systems with multiple contaminants in process plants meeting, AlChE national meeting, Dallas, TX.
3. Bagajewicz, M., Rivas, M. and Savelski, M., 2001, Algorithmic procedure to design water utilization systems featuring a single contaminant in process plants, Chem Eng Sci, 56(5): 1897-1911.
4. Cao, D., Wang, B. and Feng, X., 2004, Application of water system integration technology with water mains in catalyzer factory, Comp Appl Chem (in Chinese), 21(3): 437-439.
5. Doyle, S. J. and Smith, R., 1997, Targeting water reuse with multiple contaminants, Transactions of the Institution of Chemical Engineers, Part B, Process Saf Environ Protect, 75(3): 181-189.
6. El-Halwagi, M.M. and Manousiouthakis, V., 1989, Synthesis of mass-exchange network, AlChE J, 35(8): 1233-1244.
7. Feng, X., 2004, The Principle and Technology of Energy Saving in the Chemical Industry, 288-321 (Chemical Industry Press, Beijing, China).
8. Feng, X. and Seider, W.D., 2001, New structure and design methodology for water networks, Ind Eng Chem Res, 40(26): 6140-6146.
9. Hallale, N., 2002, A new graphical targeting method for water minimization, Adv Environ Res, 6(3): 377-390.
10. Huang, C.H., Chang, C.T., Ling, H.C. and Chang, C.C., 1999, A mathematical model for water usage and treatment network design, Ind Eng Chem Res, 38(7): 2666-2679.
11. Karuppiah, R., Ignacio, E. and Grossmann, I.E., 2006, Global optimization for the synthesis of integrated water systems in chemical processes, Comput Chem Eng, 30(4): 650-673.
12. Kuo, W.J. and Smith, R., 1998, Designing for the interactions between water-use and effluent treatment, Trans IChemE, Part A, Chem Eng Res Des, 76(A3): 287-301.
13. Li, Y. and Yao, P.J., 2004, Optimal design of water utilization networks by combination of water pinch analysis and mathematical programming. Journal of Chemical Industry and Engineering (in Chinese), 55(2): 220-225.
14. Prakotpol, D. and Srinophakun, T., 2004, GAPinch: Genetic algorithm toolbox for water pinch technology, Chem Eng Process, 43(2): 203-217.
15. Savelski, M. and Bagajewicz, M., 1999a, A new algorithmic design procedure for the design of water utilization systems in refineries and process plants, Proceedings of PRESS 99 Meeting, Budapest.
16. Savelski, M. and Bagajewicz, M., 1999b, On the use of linear models for the design of water utilization systems in refineries and process plants, Annual AlChE 1999 meeting, Dallas.
17. Savelski, M. and Bagajewicz, M., 2003, On the necessary condition of optimality of water utilization systems in process plants with multiple contaminants, Chem Eng Sci, 58(23-24): 5349-5362.
18. Takama, N., Kuriyama, T., Shiroko, K. and Umeda, T., 1980, Optimal water allocation in a petroleum refinery, Comput Chem Eng, 4(4): 251-258.
19. Ullmer, C., Kunde, N., Lassahn, A., Gruhn, G. and Schulz, K., 2005, WADO™: water design optimization - methodology and software for the synthesis of process water systems, J Clean Prod, 13(5): 485-494.
20. Wang, B., Feng, X. and Zhang, Z.X., 2003, A design methodology for multiple-contaminant water networks with single internal water main, Comput Chem Eng, 27(7): 903-911.
21. Wang, D., Yang, F. and Zhang, X., 2005, Design method for water networks with internal water mains, Journal of Chemical Industry and Engineering (in Chinese), 56(6): 1051-1056.
22. Wang, Y.P. and Smith, R., 1994a, Wastewater minimization, Chem Eng Sci, 49(7): 981-1006.
23. Wang, Y.P. and Smith, R., 1994b, Design of distributed effluent treatment systems. Chem Eng Sci, 49(18): 3127-3145.
24. Wang, Y.P. and Smith, R., 1995, Wastewater minimization with flowrate constraints, Trans IChemE, Part A, Chem Eng Res Des, 73(A8): 889-904.
25. Zheng, P.Y., Feng, X., Qian, F. and Cao, D.L., 2006a, Water system integration of a chemical plant, Energy Conv Manag, 47(15-16): 2470-2478.
26. Zheng, X., Feng, X., Shen, R. and Seider, W.D., 2006b, Design of optimal water-using networks with internal water mains, Ind Eng Chem Res, 45(25): 8413-8420.