Defective structure-containing high-entropy alloy strength prediction method

A high-entropy alloy strength prediction technology, applied in prediction, instrumentation, data processing applications, etc., can solve the problems that the theoretical model of high-entropy alloy microscopic defect strength has not been established, and the crystal plasticity theory has not been used in high-entropy alloys, etc., to achieve The effect of good application prospects

Active Publication Date: 2021-07-09
HUNAN UNIV
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Problems solved by technology

[0003] In previous studies, the research on the influence of micro-defects in high-entropy alloys on the strength of materials mostly used experimental measurement methods, and the corresponding theoret

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  • Defective structure-containing high-entropy alloy strength prediction method
  • Defective structure-containing high-entropy alloy strength prediction method
  • Defective structure-containing high-entropy alloy strength prediction method

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Embodiment Construction

[0054] The following is attached figure 1 A schematic diagram and specific examples of the model of a high-entropy alloy containing dislocation loop defects considering the three effects of dislocation, dislocation loop and lattice distortion are provided, and the technical solution is further elaborated. The present invention is not limited to the following examples. All design ideas utilizing the present invention fall within the scope of protection of the present invention.

[0055] Dislocations are mainly due to the processing and preparation of materials and service, and are used as a characterization of plastic deformation of materials; considering the main defect dislocation loops generated in FeNiMnCr high-entropy alloys during service, they are the main source of material hardening; lattice distortion is the main source of high-entropy Alloys have a strengthening effect on the mechanical properties of materials due to the inherent characteristics produced by the size...

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Abstract

The invention relates to a method for predicting the strength of a high-entropy alloy with a defect structure. A dislocation theory, a crystal plasticity theory and a defect theory are effectively combined to establish a related strength theoretical model. The influence of dislocation, a dislocation ring and a serious lattice distortion effect on the performance of the high-entropy alloy is considered, and quantitative calculation of the strength of the high-entropy alloy containing the defect structure is achieved. The yield strength obtained by the prediction method provided by the invention is well matched with an experimental result. The related deformation mechanism analyzed in the method is of great significance to research and predict the influence of dislocation ring defects on the strength of the high-entropy alloy. Through the prediction method provided by the invention, the element content of the alloy is regulated and controlled, and the influence of different element contents on the yield strength is researched, so that theoretical guidance is provided for the design of the high-performance and high-entropy alloy. In the development process of the new alloy, the method effectively avoids a large number of repeated tests, shortens the research and development period of the high-performance high-entropy alloy, saves the cost, and has huge engineering value.

Description

technical field [0001] The invention relates to the field of strength prediction of high-entropy alloys with defect-containing structures, and specifically relates to dislocation theory, crystal plasticity theory and defect theory. A theoretical model is established to consider the effects of microscopic defects and severe lattice distortion to realize the prediction of the strength of high-entropy alloys containing defects. Background technique [0002] In recent years, with the needs of modern industry, high-entropy alloys have been proposed and widely studied and used. Unlike most traditional alloys, high-entropy alloys are composed of four or more elements in equimolar or nearly equimolar amounts. Therefore, it has many excellent properties, such as high strength, high hardness, wear resistance, corrosion resistance, high temperature stability, etc. However, various microscopic defects will occur during its processing and service. For example, during the solidification...

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Application Information

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IPC IPC(8): G06F30/20G06Q10/04G06Q50/04G06F111/10G06F119/02G06F119/14
CPCG06F30/20G06Q10/04G06Q50/04G06F2119/02G06F2119/14G06F2111/10Y02P90/30
Inventor 李甲方棋洪彭静陈阳
Owner HUNAN UNIV
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