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Phase-field method-based bending dendritic crystal growth simulation method

A simulation method and bending technology, applied in the field of bending dendrite growth research, can solve the problems of long research process, difficult to meet the requirements of process precision and accuracy, and large capital expenditure

Inactive Publication Date: 2018-07-06
NANJING UNIV OF AERONAUTICS & ASTRONAUTICS
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Problems solved by technology

[0003] Traditional research is mostly based on experimental data and experience. Not only is the research process lengthy and the cost of funds is huge, but it is often difficult to meet the ever-increasing requirements for process precision and accuracy.

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  • Phase-field method-based bending dendritic crystal growth simulation method
  • Phase-field method-based bending dendritic crystal growth simulation method
  • Phase-field method-based bending dendritic crystal growth simulation method

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Embodiment Construction

[0045] The present invention is described in further detail now in conjunction with accompanying drawing.

[0046] The curved dendrite growth simulation method based on the phase field method provided by the present invention can establish a two-dimensional dendrite growth model in the solidification process. The simulation method is based on the phase field method to simplify the simulation conditions and establish the macroscopic temperature field and transient advancement. For the velocity model, the macroscopic model and the phase field model are coupled and superimposed, and the state, time and area are discretized, and the calculation, update and calculation result are exported at each time step, and so on until the end of the calculation.

[0047] Such as figure 1 As shown, the simulation method specifically includes the following steps:

[0048] 1. Simplify the conditions and model initialization, and build the model according to the actual situation.

[0049] In ord...

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Abstract

The invention relates to a phase-field method-based bending dendritic crystal growth simulation method. The phase-field method-based bending dendritic crystal growth simulation method comprises the following steps: simplifying conditions and initializing a model; establishing a macroscopic temperature field equation and a transient dendritic crystal growth deviation angle equation; establishing amicrostructure evolution model and establishing a phase field model for simulating bending dendritic crystal growth based on a Ginzburg-Landau theory; and performing macroscopic-microcosmic coupling calculation, introducing a macroscopic temperature field and a dendritic crystal growth deviation angle into the field phase model, and calculating the growth process of the bending dendritic crystal to finally obtain the shape of the bending dendritic crystal. According to the phase-field method-based bending dendritic crystal growth simulation method, formation of the bending dendritic crystal inthe solidification process can be simulated and predicted quantitatively, the formation process of the solidified microstructure dynamically reappears, deep understanding of the evolution process ofthe solidified microstructure is facilitated, and basis is laid for microstructure evolution research and process optimization.

Description

technical field [0001] The invention belongs to the field of research on the growth of curved dendrites, in particular to a method for simulating the growth of curved dendrites based on a phase field method. Background technique [0002] The solidification process has always been a key research topic of many researchers, because the complex solidification process can determine the final solidification microstructure of the component, thereby affecting its mechanical properties. Studying and studying the complex solidification process and the final microstructure formed can provide valuable theoretical basis and data experience for process optimization. [0003] Traditional research is mostly based on experimental data and experience. Not only is the research process lengthy and the cost of funds is huge, but it is often difficult to meet the ever-increasing requirements for process precision and accuracy. With the rapid development of computer technology and the continuous ...

Claims

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Application Information

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IPC IPC(8): G01N31/00
CPCG01N31/00
Inventor 魏艳红王磊刘仁培
Owner NANJING UNIV OF AERONAUTICS & ASTRONAUTICS
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