International Journal of Environment Science and Technology
Center for Environment and Energy Research and Studies (CEERS)
Vol. 5, No. 2, 2008, pp. 251-262
Bioline Code: st08029
Full paper language: English
Document type: Research Article
Document available free of charge
International Journal of Environment Science and Technology, Vol. 5, No. 2, 2008, pp. 251-262
© Copyright 2008 Center for Environment and Energy Research and Studies (CEERS)
Application of an environmentally optimum cooling water system design to water and energy conservation|
Panjeshahi, M. H. & Ataei, A.
Recirculating cooling water systems are consist of a cooling tower and heat-exchanger network which conventionally have a parallel configuration. However, reuse of water between different cooling duties enables cooling water networks to be designed with series arrangements. This will result in performance improvement and increased cooling tower capacity. Research on recirculating cooling water systems has mostly focused on the individual components. However, a particular design method represented by Kim and Smith accounts for the whole system interactions. In this study, the Kim and Smith design method is expanded and a comprehensive simulation model of recirculating cooling system was developed to account for the interaction between the cooling tower performance and the heat-exchanger network configuration. Regarding this model and considering cycle water quality through introducing ozone treatment technology, a modern methodology of recirculating cooling water system design was established and developed. This technique, called the integrated ozone treatment cooling system design, is a superior designed tool based on pinch analysis and mathematical programing. It also ensures maximum water and energy conservation, minimum cost and environmental impacts. Related coding in MATLAB version 7.3 was used for the illustrative example to get optimal values in cooling water design method computations. The result of the recently introduced design methodology was compared with the Kim and Smith design method.
Environmental impacts,ozone treatment, pinch analysis, mathematical programing, heat-exchanger network
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