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Fluid-solid node two-phase flow modeling method

A modeling method and fluid technology, applied in design optimization/simulation, special data processing applications, instruments, etc., can solve problems such as poor quality and inability to give a temperature field

Active Publication Date: 2016-04-20
BEIHANG UNIV
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Problems solved by technology

Although this method has high computational efficiency, the quality of the calculation results is poor and cannot give an accurate temperature field

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Embodiment Construction

[0014] According to the fluid-solid node-based two-phase flow modeling method of the present invention, the two-phase fluid is abstracted into a node with a certain temperature, mass, and volume, and is processed with the idea of ​​a node thermal network to avoid multi-phase flow CFD calculation. At the same time, the method of numerical heat transfer is still used to solve the transient heat transfer in the solid region to ensure the quality of the calculation results of the temperature in the solid region. Since the fluid is noded in the calculation, the surface radiation heat transfer model (S2S) that does not rely on the fluid region is selected as the radiation model.

[0015] Such as figure 1 As shown, the fluid-solid nodal two-phase flow modeling method according to an embodiment of the present invention includes:

[0016] 1) Abstract liquid phase and gas phase respectively as "nodes" with temperature, mass and volume;

[0017] 2) Calculate the volume of the gas phase...

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Abstract

The invention discloses a fluid-solid node two-phase flow modeling method used for achieving gravity-driven fluid-structure interaction heat transfer of two-phase flow without phase change. The method is characterized in that accurate calculation of a flow field is ignored, and the two-phase flow is processed according to a node thermal network thought. The method specifically comprises the steps that A, a liquid phase and a gas phase are abstracted into nodes with certain mass, volume and temperature; B, a gravity direction volume integral is used for calculating the interface between the two phases; C, a surface radiation heat transfer model is used for calculating the radiation heat flux density of a fluid-structure interaction wall; D, the temperature of the gas phase and the temperature of the liquid phase are calculated according to the heat convection heat flux density of the fluid-structure interaction wall; E, solid transient heat conduction is calculated according to the total heat flux density of the fluid-structure interaction wall. Targeting the fluid-structure interaction heat transfer process of the two-phase flow in a typical fuel tank, compared with a calculated result obtained through a Fluent business software phase field method, the calculated result obtained through the modeling method better reflects the influence of the phase interface on heat transfer, calculation efficiency is improved by one order of magnitude, and the engineering calculation demand is met.

Description

technical field [0001] The invention relates to a fluid-solid nodal two-phase flow modeling method. Background technique [0002] At present, there are mainly two methods to solve the gravity-driven simple two-phase fluid-solid coupling heat transfer problem in engineering. [0003] The first method solves the flow field in the two-phase flow region with a "phase field" approach based on the diffusion interface, coupled with the solid in real time. Mainly used in commercial CFD (computational fluid dynamics) software, such as FLUENT. The "phase field" method uses the order parameter φ a (x,t), φ b (x,t) models the spatial distribution of two phases a, b. In the region φ occupied by phase a a (x,t) is equal to 1, in the region where phase a does not exist φ a (x,t) is equal to 0, and in the diffusion interface around phase a φ a (x,t) varies continuously between 1 and 0. At any position in the flow field, φ a (x,t) and φ b The sum of (x,t) is equal to 1. In the dif...

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G06F17/50
CPCG06F30/20G06F2119/08
Inventor 董素君江鸿升孟繁超
Owner BEIHANG UNIV
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