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《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]

Issue:

2023年03期

Page:

26-33

Research Field:

目次

Publishing date:

Info

Title:

Numerical analysis and model establishment on effective pore diameter of Dutch twill weave

Author(s):

MA Yuan¹;  DONG Yan¹;  LI Jian¹;  LI Yanzhong¹;  WANG Bin²;  HE Peng²

(1.Department of Refrigeration and Cryogenics, Xi'an Jiaotong University, Xi'an 710049, China; 2.Shanghai Aerospace System Engineering Institute, Shanghai 201109, China)

Keywords:

cryogenic propellant;  orbital gas-liquid separation;  Dutch twill weave;  bubble point pressure;  effective pore diameter

PACS:

V511⁺.6

DOI:

-

Abstract:

Bubble point pressure is one of the key indexes to characterize the gas-liquid separation performance of the screen channel liquid acquisition devices, and the effective pore diameter of the screen is the core parameter to accurately predict the bubble point pressure. In the face of the limitation that the existing research is still mainly based on the experimental measuring method to obtain the effective pore diameter of screens, the structural characteristics of the fluid domain within the screen are obtained by constructing the three-dimensional geometry model of the real structure of Dutch twill weave(DTW)in this paper. The numerical study on the bubble point pressure at the characteristic throat is conducted based on the surface tension model and pressure boundary setting. A calculation model of effective pore diameter based on geometrical structure parameters of screen is proposed. The results show that the characteristic throat, which determines the bubble point pressure of DTW, is located near z=±(r_w+r_s)and is of a nearly closed quadrilateral boundary. In view of the characteristic throat section, the prediction of the effective pore diameter derived from the numerical simulation of bubble point pressure, is of a relative error less than 6% compared to the experimental data in literatures. Through the proposed effective pore diameter model, the predicted results are also in good agreement with literatures' experimental data, and the average error is less than 10%. The accurate prediction of thescreen's effective pore diameter can be achieved and is independent of the experimental measurement, which could provide important support for the performance analysis of screen's bubble point pressure and the design optimization of liquid acquisition devices.

References:

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