Your search keyword '"Xiaocheng Zhang"' showing total 2 results

1. New Inverse Method for Determining Uniaxial Flow Properties by Spherical Indentation Test

Author

Guoyao Chen, Xiaocheng Zhang, Jiru Zhong, Jin Shi, Qiongqi Wang, and Kaishu Guan

Subjects

Spherical indentation test, Database method, Uniaxial stress-strain relationship, Ocean engineering, TC1501-1800, Mechanical engineering and machinery, TJ1-1570

Abstract

Abstract The spherical indentation test has been successfully applied to inversely derive the tensile properties of small regions in a non-destructive way. Current inverse methods mainly rely on extensive iterative calculations, which yield a considerable computational costs. In this paper, a database method is proposed to determine tensile flow properties from a single indentation force-depth curves to avoid iterative simulations. Firstly, a database that contain numerous indentation force-depth curves is established by inputting varied Ludwic material parameters into the indentation finite elements model. Secondly, for a given experimental indentation curve, a mean square error (MSE) is designated to evaluate the deviation between the experimental curve and each curve in the database. Finally, the true stresses at a series of plastic strain can be acquired by analyzing these deviations. To validate this new method, three different steels, i.e. A508, 2.25Cr1Mo and 316L are selected. Both simulated indentation curves and experimental indentation curves are used as inputs of the database to inversely acquire the flow properties. The result indicates that the proposed approach provides impressive accuracy when simulated indentation curves are used, but is less accurate when experimental curves are used. This new method can derive tensile properties in a much higher efficiency compared with traditional inverse method and are therefore more adaptive to engineering application.

Published

2021

2. New Inverse Method for Determining Uniaxial Flow Properties by Spherical Indentation Test

Author

Xiaocheng Zhang, Jiru Zhong, Jin Shi, Kaishu Guan, Qiongqi Wang, and Guoyao Chen

Subjects

Yield (engineering), Materials science, Mean squared error, Series (mathematics), Mechanical Engineering, Mathematical analysis, Spherical indentation test, Plasticity, Industrial and Manufacturing Engineering, Finite element method, Database method, Ocean engineering, Indentation, Uniaxial stress-strain relationship, Ultimate tensile strength, TJ1-1570, Mechanical engineering and machinery, TC1501-1800, Inverse method

Abstract

The spherical indentation test has been successfully applied to inversely derive the tensile properties of small regions in a non-destructive way. Current inverse methods mainly rely on extensive iterative calculations, which yield a considerable computational costs. In this paper, a database method is proposed to determine tensile flow properties from a single indentation force-depth curves to avoid iterative simulations. Firstly, a database that contain numerous indentation force-depth curves is established by inputting varied Ludwic material parameters into the indentation finite elements model. Secondly, for a given experimental indentation curve, a mean square error (MSE) is designated to evaluate the deviation between the experimental curve and each curve in the database. Finally, the true stresses at a series of plastic strain can be acquired by analyzing these deviations. To validate this new method, three different steels, i.e. A508, 2.25Cr1Mo and 316L are selected. Both simulated indentation curves and experimental indentation curves are used as inputs of the database to inversely acquire the flow properties. The result indicates that the proposed approach provides impressive accuracy when simulated indentation curves are used, but is less accurate when experimental curves are used. This new method can derive tensile properties in a much higher efficiency compared with traditional inverse method and are therefore more adaptive to engineering application.

Published

2021