Synthesis of the fluid machinery network in a circulating water system

doi:10.1016/j.cjche.2018.06.030

Chinese Journal of Chemical Engineering ›› 2019, Vol. 27 ›› Issue (3): 587-597.DOI: 10.1016/j.cjche.2018.06.030

• Process Systems Engineering and Process Safety • 上一篇下一篇

Synthesis of the fluid machinery network in a circulating water system

Wei Gao, Xiao Feng

School of Chemical Engineering and Technology, Xi'an Jiaotong University, Xi'an 710049, China

收稿日期:2018-04-18 修回日期:2018-06-29 出版日期:2019-03-28 发布日期:2019-04-25
通讯作者: Xiao Feng,E-mail address:xfeng@xjtu.edu.cn
基金资助:
Supported by the National Natural Science Foundation of China (21736008).

Synthesis of the fluid machinery network in a circulating water system

Wei Gao, Xiao Feng

School of Chemical Engineering and Technology, Xi'an Jiaotong University, Xi'an 710049, China

Received:2018-04-18 Revised:2018-06-29 Online:2019-03-28 Published:2019-04-25
Contact: Xiao Feng,E-mail address:xfeng@xjtu.edu.cn
Supported by:
Supported by the National Natural Science Foundation of China (21736008).

摘要/Abstract

摘要： Energy consumption of the fluid machinery network in a circulating water system takes up a large part of energy consumption in the process industry, so optimization on the network will enhance the economic and environmental performance of the industry. In this paper, a synthesis approach is proposed to obtain the optimal network structure. The effective height curves are used as tools to perform energy analysis, so that the potential placement of water turbines and auxiliary pumps can be determined with energy benefit. Then economic optimization is carried out, by the mathematical model with the total cost as the objective function, to identify the branches for water turbines and auxiliary pumps with economic benefit. In this way, the optimal fluid machinery network structure can be obtained. The results of case study indicate that the proposed synthesis approach to optimize the fluid machinery network will obtain more remarkable benefits on economy, compared to optimizing only the water turbine network or pump network. The results under different flowrates of circulating water reveal that using a water turbine to recover power or adding an auxiliary pump to save energy in branches are only suitable to the flowrate in a certain range.

关键词: Fluid machinery network, Synthesis approach, Flowrate range, Network structure

Abstract: Energy consumption of the fluid machinery network in a circulating water system takes up a large part of energy consumption in the process industry, so optimization on the network will enhance the economic and environmental performance of the industry. In this paper, a synthesis approach is proposed to obtain the optimal network structure. The effective height curves are used as tools to perform energy analysis, so that the potential placement of water turbines and auxiliary pumps can be determined with energy benefit. Then economic optimization is carried out, by the mathematical model with the total cost as the objective function, to identify the branches for water turbines and auxiliary pumps with economic benefit. In this way, the optimal fluid machinery network structure can be obtained. The results of case study indicate that the proposed synthesis approach to optimize the fluid machinery network will obtain more remarkable benefits on economy, compared to optimizing only the water turbine network or pump network. The results under different flowrates of circulating water reveal that using a water turbine to recover power or adding an auxiliary pump to save energy in branches are only suitable to the flowrate in a certain range.

Key words: Fluid machinery network, Synthesis approach, Flowrate range, Network structure

Wei Gao, Xiao Feng. Synthesis of the fluid machinery network in a circulating water system[J]. Chinese Journal of Chemical Engineering, 2019, 27(3): 587-597.

Wei Gao, Xiao Feng. Synthesis of the fluid machinery network in a circulating water system[J]. Chin.J.Chem.Eng., 2019, 27(3): 587-597.

参考文献 20

[1]	G. Liu, H. Zhou, R. Shen, X. Feng, A graphical method for integrating work exchange network, Appl. Energy 114(2014) 588-599.
[2]	M.S. Razib, M.M.F. Hasan, I.A. Karimi, Preliminary synthesis of work exchange networks, Comput. Chem. Eng. 37(2012) 262-277.
[3]	H. Zhou, G. Liu, X. Feng, Problem table method for work exchange network with efficiency considered, CIESC J. 62(2011) 1600-1605.
[4]	Y. Zhuang, L. Liu, Q. Liu, J. Du, Step-wise synthesis of work exchange networks involving heat integration based on the transshipment model, Chin. J. Chem. Eng. 25(2017) 1052-1060.
[5]	C. Cheng, S. Cheng, L. Fan, Flow work exchanger, AIChE J. 13(1967) 438-442.
[6]	X. Feng, H. Chen, Optimized work exchange networks with economic consideration, J. Tsinghua Univ. Sci. Technol. 52(2012) 298-302.
[7]	W. Gao, X. Feng, The power target of a fluid machinery network in a circulating water system, Appl. Energy 205(2017) 847-854.
[8]	Y. Zeng, Z. Zhang, A. Kusiak, F. Tang, X. Wei, Optimizing wastewater pumping system with data-driven models and a greedy electromagnetism-like algorithm, Stoch. Env. Res. Risk A. 30(2016) 1263-1275.
[9]	J. Sun, X. Feng, Y. Wang, C. Deng, K.H. Chu, Pump network optimization for a cooling water system, Energy 67(2014) 506-512.
[10]	J. Sun, X. Feng, Y. Wang, Cooling-water system optimization with a novel two-step sequential method, Appl. Therm. Eng. 89(2015) 1006-1013.
[11]	J. Ma, Y. Wang, X. Feng, Simultaneous optimization of pump and cooler networks in a cooling water system, Appl. Therm. Eng. 125(2017) 377-385.
[12]	Y. Wang, K.H. Chu, Z. Wang, Two-step methodology for retrofit design of cooling water networks, Ind. Eng. Chem. Res. 53(2014) 274-286.
[13]	B. Coelho, A. Andrade-Campos, Energy recovery in water networks:numerical decision support tool for optimal site and selection of micro turbines, J. Water Resour. Plan. Manag. 144(2018) (04018004).
[14]	Y. Gao, J. Li, The application of hydraulic turbine energy-saving technology in circulating water cooling towers in the petrochemical industry, Sino Glob. Energy 19(2014) 98-101.
[15]	H.M. Ramos, M. Mello, P.K. De, Clean power in water supply systems as a sustainable solution:from planning to practical implementation, Water Sci. Technol. Water Supply 79(2010) 24-26.
[16]	W. Gao, X. Feng, The optimal model of a fluid machinery network in a circulating water system, Chem. Eng. Trans. 61(2017) 91-96.
[17]	J. Ma, Y. Wang, X. Feng, Energy recovery in cooling water system by hydro turbines, Energy 139(2017) 329-340.
[18]	W. Gao, X. Feng, Pressure distribution analysis on circulating water pump networks, Energy Conserv. Pet. Petrochem. Ind. (2016) 12-14.
[19]	W. Seider, J.D. Seader, D. Lewin, Process design principles, John Wiley and Sons, Inc., New York, 2009.
[20]	V. Sammartano, G. Morreale, M. Sinagra, A. Collura, T. Tucciarelli, Experimental study of cross-flow micro-turbines for aqueduct energy recovery, Procedia Eng. 89(2014) 540-547.

Synthesis of the fluid machinery network in a circulating water system

Synthesis of the fluid machinery network in a circulating water system

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