High-temperature alloy component design method based on material gene engineering technology

The invention discloses a high-temperature alloy component design method based on material gene engineering, and belongs to the field of component design of metal materials. A component design space is formed by determining alloy element types and component ranges, alloy design requirements are form...

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Hauptverfasser:	LI ZIXIN, FU HUADONG, XIE JIANXIN, PENG ZICHAO, WANG XUQING
Format:	Patent
Sprache:	chi ; eng
Schlagworte:	CALCULATING COMPUTING COUNTING ELECTRIC DIGITAL DATA PROCESSING INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTEDFOR SPECIFIC APPLICATION FIELDS PHYSICS
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creator	LI ZIXIN FU HUADONG XIE JIANXIN PENG ZICHAO WANG XUQING
description	The invention discloses a high-temperature alloy component design method based on material gene engineering, and belongs to the field of component design of metal materials. A component design space is formed by determining alloy element types and component ranges, alloy design requirements are formulated, and the aspects of material cost, density, structure stability, service performance and the like are started; the method comprises the following steps: collecting alloy historical data, establishing a high-temperature alloy component-service performance data set, constructing one or more service performance models by utilizing a machine learning method, evaluating by utilizing a method of combining high-throughput thermodynamic calculation and high-throughput experiment, and predicting alloy components, density, alloy structure stability and service performance. A complete alloy component design method is formed, and accurate and efficient high-temperature alloy component design is achieved. According to th
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A component design space is formed by determining alloy element types and component ranges, alloy design requirements are formulated, and the aspects of material cost, density, structure stability, service performance and the like are started; the method comprises the following steps: collecting alloy historical data, establishing a high-temperature alloy component-service performance data set, constructing one or more service performance models by utilizing a machine learning method, evaluating by utilizing a method of combining high-throughput thermodynamic calculation and high-throughput experiment, and predicting alloy components, density, alloy structure stability and service performance. A complete alloy component design method is formed, and accurate and efficient high-temperature alloy component design is achieved. 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subjects	CALCULATING COMPUTING COUNTING ELECTRIC DIGITAL DATA PROCESSING INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTEDFOR SPECIFIC APPLICATION FIELDS PHYSICS
title	High-temperature alloy component design method based on material gene engineering technology
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