Optimization of the fuel rod＇s arrangement cooled by turbulentnanofluids flow in pressurized water reactor (PWR)

Optimization of the fuel rod's arrangement cooled by turbulent nanofluids flow in pressurized water reactor(PWR)

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摘要 In this paper, response surface methodology(RSM) based on central composite design(CCD) is applied to obtain an optimization design for the fuel rod's diameter and distance cooled by turbulent Al_2O_3–water nanofluid for a typical pressurized water reactor(PWR). Fuel rods and nanofluid flow between them are simulated 3D using computational fluid dynamics(CFD) by ANSYS-FLUNET package software. The RNG k–ε model is used to simulate turbulent nanofluid flow between the rods. The effect of different nanoparticles concentration is also investigated on the Nusselt number from heat transfer efficiency view point. Results reveal that when distance parameter(a) is in the minimum level and diameter parameter(r) is in the maximum possible level, cooling the rods will be better due to higher Nusselt number in this situation. Also, using the different nanoparticles on the cooling process confirms that Al_2O_3 averagely 17% and TiO_2 10% improve the Nusselt numbers. In this paper, response surface methodology(RSM) based on central composite design(CCD) is applied to obtain an optimization design for the fuel rod's diameter and distance cooled by turbulent Al_2O_3–water nanofluid for a typical pressurized water reactor(PWR). Fuel rods and nanofluid flow between them are simulated 3D using computational fluid dynamics(CFD) by ANSYS-FLUNET package software. The RNG k–ε model is used to simulate turbulent nanofluid flow between the rods. The effect of different nanoparticles concentration is also investigated on the Nusselt number from heat transfer efficiency view point. Results reveal that when distance parameter(a) is in the minimum level and diameter parameter(r) is in the maximum possible level, cooling the rods will be better due to higher Nusselt number in this situation. Also, using the different nanoparticles on the cooling process confirms that Al_2O_3 averagely 17% and TiO_2 10% improve the Nusselt numbers.

作者 M. Hatami MJ.Z. Ganfi I. Sohrabiasl D. Jing

机构地区 International Research Center for Renewable Energy Department of Mechanical Engineering Department of Renewable Energies Engineering Department of Mechanical Engineering

出处《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2017年第6期722-731,共10页 中国化学工程学报（英文版）

基金 financial support of the National Natural Science Foundation of China (No. 51422604, 21276206) the National 863 Program of China (No. 2013AA050402) supported by the China Fundamental Research Funds for the Central Universities

关键词 OPTIMIZATION FUEL RODS NANOFLUID Pressurized water REACTOR Optimization Fuel rods Nanofluid Pressurized water reactor

分类号 TQ021.1 [化学工程]

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参考文献3

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Chinese Journal of Chemical Engineering

2017年第6期

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Optimization of the fuel rod＇s arrangement cooled by turbulentnanofluids flow in pressurized water reactor (PWR)

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