Numerical study on water draining process pushed by nitrogen in EAST upper divertor

•The study on drainage process for the EAST divertor was firstly carried out.•The pressure difference between the outlet and inlet of the divertor should be at least of 4 KPa to effectively blow the residual water out of the cooling channels of the upper divertor.•The hydraulic characteristics of dr...

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Bibliographic Details
Published inFusion engineering and design Vol. 170; p. 112545
Main Authors Li, Weibao, Hu, Jiansheng, Fu, Peng, Yang, Lei, Guo, Bin, Zhu, Lili, Xu, Tiejun, Cao, Lei
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.09.2021
Elsevier Science Ltd
Subjects
Blowouts
Channels
Cooling
Divertor
Drainage
Drainage systems
EAST Tokamak
Flow velocity
FLUENT analysis
Gas pressure
Gas-liquid
Pressure distribution
Two phase flow
Water flow
EAST Tokamak
Drainage
Gas-liquid
Divertor
FLUENT analysis
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Summary:•The study on drainage process for the EAST divertor was firstly carried out.•The pressure difference between the outlet and inlet of the divertor should be at least of 4 KPa to effectively blow the residual water out of the cooling channels of the upper divertor.•The hydraulic characteristics of drainage process were analyzed in detail, such as the water volume fraction, flow velocity, the draining water flow rate, and the pressure distribution. In the Experimental Advanced Superconducting Tokamak (EAST), the water in the cooling channels of the upper divertor is difficult to be pushed out by the current drainage system resulting in the possible divertor damage. Therefore, studies on the draining process using the gas pushing for this divertor is essential to improve the current drainage system. In this paper, the hydraulic characteristics of the developing gas-liquid two-phase flow were investigated in detail by using the FLUENT code. The results showed that the pressure difference between the inlet and outlet of the cooling channel should be larger than 4 kPa to effectively blow out the residual water from the cooling channels by the nitrogen gas pressure. Also, it was found that the draining process can be divided into five stages in regards to the different hydraulic characteristics, such as the flow velocity, the draining water flow rate, and the pressure distribution. These results will provide a theoretical basis for future improvements in the EAST drainage systems.
ISSN:0920-3796
1873-7196
DOI:10.1016/j.fusengdes.2021.112545