Litcius/Paper detail

Multi-scale impact resistance of flexible microporous metal rubber: Dynamic energy dissipation mechanism based on dynamic friction locking effect

Qiang Song, Liangliang Shen, Linwei Shi, Ling Pan, Ang Wang, Zhiying Ren

2025Defence Technology8 citationsDOIOpen Access PDF

Abstract

Flexible microporous metal rubber (FMP-MR) is widely used in national defense applications, yet its mechanical behavior under high-speed impact conditions remains insufficiently explored. In this study, dynamic and static experiments were conducted to systematically investigate the mechanical response of metal-wrapped microporous materials under impact loading that spanned 10 6 orders of magnitude. By combining a high-precision numerical model with a spatial contact point search algorithm, the spatio–temporal contact characteristics of the complex network structure in FMP-MR were systematically analyzed. Furthermore, the mapping mechanism from turn topology and mesoscopic friction behavior to macroscopic mechanical properties was comprehensively explored. The results showed that compared with quasi-static loading, FMP-MR under high-speed impact exhibited higher energy absorption efficiency due to high-strain-rate inertia effect. Therefore, the peak stress increased by 141%, and the maximum energy dissipation increased by 300%. Consequently, the theory of dynamic friction locking effect was innovatively proposed. The theory explains that the close synergistic effect of sliding friction and plastic dissipation promoted by the stable interturn-locked embedded structure is the essential reason for the excellent dynamic mechanical properties of FMP-MR under dynamic loading conditions. Briefly, based on the in-depth investigation of the mechanical response and energy dissipation mechanism of FMP-MR under impact loads, this study provides a solid theoretical basis for further expanding the application range of FMP-MR and optimizing its performance.

Topics & Concepts

DissipationMicroporous materialMechanism (biology)Materials scienceDynamical frictionNatural rubberScale (ratio)Composite materialStructural engineeringEngineeringPhysicsThermodynamicsQuantum mechanicsCellular and Composite StructuresTribology and Wear AnalysisElasticity and Material Modeling
Multi-scale impact resistance of flexible microporous metal rubber: Dynamic energy dissipation mechanism based on dynamic friction locking effect | Litcius