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http://dx.doi.org/10.9713/kcer.2014.52.5.603

Development of a Deterministic Optimization Model for Design of an Integrated Utility and Hydrogen Supply Network  

Hwangbo, Soonho (Department of Chemical Engineering, POSTECH)
Han, Jeehoon (Department of Chemical and Biological Engineering, University of Wisconsin-Madison)
Lee, In-Beum (Department of Chemical Engineering, POSTECH)
Publication Information
Korean Chemical Engineering Research / v.52, no.5, 2014 , pp. 603-612 More about this Journal
Abstract
Lots of networks are constructed in a large scale industrial complex. Each network meet their demands through production or transportation of materials which are needed to companies in a network. Network directly produces materials for satisfying demands in a company or purchase form outside due to demand uncertainty, financial factor, and so on. Especially utility network and hydrogen network are typical and major networks in a large scale industrial complex. Many studies have been done mainly with focusing on minimizing the total cost or optimizing the network structure. But, few research tries to make an integrated network model by connecting utility network and hydrogen network In this study, deterministic mixed integer linear programming model is developed for integrating utility network and hydrogen network. Steam Methane Reforming process is necessary for combining two networks. After producing hydrogen from Steam-Methane Reforming process whose raw material is steam vents from utility network, produced hydrogen go into hydrogen network and fulfill own needs. Proposed model can suggest optimized case in integrated network model, optimized blueprint, and calculate optimal total cost. The capability of the proposed model is tested by applying it to Yeosu industrial complex in Korea. Yeosu industrial complex has the one of the biggest petrochemical complex and various papers are based in data of Yeosu industrial complex. From a case study, the integrated network model suggests more optimal conclusions compared with previous results obtained by individually researching utility network and hydrogen network.
Keywords
Hydrogen Network; Utility Network; Deterministic Mixed Integer Linear Programming; Steam-Methane Reforming Process;
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Times Cited By KSCI : 3  (Citation Analysis)
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