An indentation method to determine the constitutive parameters of hyperelastic films under large deformation: Theoretical model, experiments and simulations

The characterization of the mechanical properties of soft films is of great importance for their applications. In our previous research, we demonstrate the existence of a maximum load occurring during the indentation process of a perforated film by a spherical indenter. Based on this result, an appr...

Full description

Saved in:
Bibliographic Details
Published in:International journal of solids and structures 2024-11, Vol.304, p.113007, Article 113007
Main Authors: Che, Haoyuan, Ben Amar, Martine, Zhu, Wei, Fan, Shengjun, Leng, Jinsong, Jia, Fei, Liu, Yanju
Format: Article
Language:English
Subjects:
Elastic modulus
Friction
Indentation method
Porous film
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The characterization of the mechanical properties of soft films is of great importance for their applications. In our previous research, we demonstrate the existence of a maximum load occurring during the indentation process of a perforated film by a spherical indenter. Based on this result, an approach to obtain the shear modulus of the film material using the method of finite element analysis has been proposed. However, our previous work does not consider the effect of friction between the film and the indenter, which has a significant influence on the value of the maximum load. Here, a theoretical model is presented which takes into account the role of friction. The reliability and accuracy of the theoretical model are validated by comparison with simulations and experimental results. In addition, the indenter eccentricity and round hole shape deviations which commonly occur in actual indentation tests, are investigated by combining indentation test measurements with finite element analysis. The performance of this method on porous films is also analyzed experimentally and numerically. The results reveal that this indentation method is still effective for porous films. This work provides a fundamental understanding of the mechanism of the indentation method and is expected to provide a new perspective for local characterization of films, even with multiple holes. •A theoretical model of the indentation method considering the effects of friction is proposed.•The indenter eccentricity and round hole shape deviation are investigated.•The validity of the theoretical model is verified by simulations and experimetns.•The indentation method is extended to porous materials by numerical and experimental analysis.
ISSN:0020-7683
DOI:10.1016/j.ijsolstr.2024.113007