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Simultaneous synthesis of non-isothermal water networks integrated with process streams

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  • Ibrić, Nidret
  • Ahmetović, Elvis
  • Kravanja, Zdravko
  • Maréchal, François
  • Kermani, Maziar

Abstract

This paper is an extension of our previous study [1] and addresses simultaneous synthesis of non-isothermal water networks heat-integrated with hot and cold process streams. Hence, the scope of heat integration is expanded by enabling heat integration of process streams such as waste gas streams and reactor feed and effluent streams simultaneously with the water network's hot and cold streams. A recently proposed superstructure [2] for the synthesis of non-isothermal water networks is extended in order to enable additional heat integration options with process streams. The model and solution strategy are modified in order to enable achieving the solution of the problem within the reasonable computational time. Pseudo heat exchanger cost was introduced in order to find heat exchange matches. They are used as constraints within the mixed-integer nonlinear programming (MINLP) model that simultaneously addresses the synthesis problem. The objective function of the proposed model accounts for operating costs, including fresh water, utilities and treatment operating cost, and investment costs of heat exchangers and treatment units. The results indicate that by solving a unified network, rather than stand-alone non-isothermal water network and separate process heat exchange network, additional savings in utilities consumption and total annualised cost can be achieved.

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  • Ibrić, Nidret & Ahmetović, Elvis & Kravanja, Zdravko & Maréchal, François & Kermani, Maziar, 2017. "Simultaneous synthesis of non-isothermal water networks integrated with process streams," Energy, Elsevier, vol. 141(C), pages 2587-2612.
  • Handle: RePEc:eee:energy:v:141:y:2017:i:c:p:2587-2612
    DOI: 10.1016/j.energy.2017.07.018
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    References listed on IDEAS

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    1. Arne Stolbjerg Drud, 1994. "CONOPT—A Large-Scale GRG Code," INFORMS Journal on Computing, INFORMS, vol. 6(2), pages 207-216, May.
    2. Ahmetović, Elvis & Kravanja, Zdravko, 2013. "Simultaneous synthesis of process water and heat exchanger networks," Energy, Elsevier, vol. 57(C), pages 236-250.
    3. Leewongtanawit, Boondarik & Kim, Jin-Kuk, 2009. "Improving energy recovery for water minimisation," Energy, Elsevier, vol. 34(7), pages 880-893.
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    5. Hong, Xiaodong & Liao, Zuwei & Jiang, Binbo & Wang, Jingdai & Yang, Yongrong, 2016. "Simultaneous optimization of heat-integrated water allocation networks," Applied Energy, Elsevier, vol. 169(C), pages 395-407.
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    7. Ahmetović, Elvis & Ibrić, Nidret & Kravanja, Zdravko, 2014. "Optimal design for heat-integrated water-using and wastewater treatment networks," Applied Energy, Elsevier, vol. 135(C), pages 791-808.
    8. Martínez-Patiño, Jesús & Picón-Núñez, Martín & Serra, Luis M. & Verda, Vittorio, 2011. "Design of water and energy networks using temperature–concentration diagrams," Energy, Elsevier, vol. 36(6), pages 3888-3896.
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    Cited by:

    1. Maziar Kermani & Ivan D. Kantor & François Maréchal, 2019. "Optimal Design of Heat-Integrated Water Allocation Networks," Energies, MDPI, vol. 12(11), pages 1-31, June.
    2. Zirngast, Klavdija & Kravanja, Zdravko & Novak Pintarič, Zorka, 2021. "An improved algorithm for synthesis of heat exchanger network with a large number of uncertain parameters," Energy, Elsevier, vol. 233(C).
    3. Kamat, Shweta & Bandyopadhyay, Santanu, 2021. "A hybrid approach for heat integration in water conservation networks through non-isothermal mixing," Energy, Elsevier, vol. 233(C).
    4. Ibrić, Nidret & Ahmetović, Elvis & Kravanja, Zdravko & Grossmann, Ignacio E., 2021. "Simultaneous optimisation of large-scale problems of heat-integrated water networks," Energy, Elsevier, vol. 235(C).
    5. Maziar Kermani & Ivan D. Kantor & François Maréchal, 2018. "Synthesis of Heat-Integrated Water Allocation Networks: A Meta-Analysis of Solution Strategies and Network Features," Energies, MDPI, vol. 11(5), pages 1-28, May.

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