Contact of Rough Surfaces: An Incremental Model Accounting for Strain Gradient Plasticity

Jiang, Chunyun; Yuan, Weike; Zheng, Yanbin; Wang, Gangfeng

doi:10.3390/lubricants11030140

Cited by 4 publications

(1 citation statement)

References 41 publications

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“…In many studies, FEM simulations offer an alternative and convenient method to investigate rough surface contact considering complex influencing factors [21], for example the nonlinearity of materials. Song [22], Zhang [23], and Jiang [24] studied the contact behaviors of rough surfaces by taking size dependence into account. Zhang and Yang [25] noted that the indentation behaviors of hyperelastic spheres primarily depend on the combined influences of substantial deformation and material nonlinearity.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of an Incremental Contact Model for Hyperelastic Solids Using an In Situ Optical Interferometric Technique

Zheng,

Jiang

2024

Lubricants

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The intricacies of rough surface contact are amplified by hyperelastic materials, primarily due to nonlinear enhancement caused by stress concentration. In previous studies, we proposed an incremental contact model for hyperelastic materials based on the tangent modulus and validated it through finite element simulations. This study proceeds with the experimental validation of the model. Initially, four hyperelastic rough surfaces were scanned and stitched together using a white light interferometer to obtain the whole surface topography. Subsequently, in situ optical interferometric techniques precisely measured the actual contact areas between these four samples and quartz glass, establishing the relationship between the load and contact area. Finally, by incorporating the surface topography into the incremental contact model for hyperelastic materials using profile theory, predictions of the relationship between load and contact area were made and compared with the experimental results. Significant agreement was found within nearly 90% of the relative contact area, which validated the model’s efficacy. The importance of this model extends to practical domains, such as wear, sealing, and contact surface safety research.

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Section: Introductionmentioning

confidence: 99%

Experimental Investigation of an Incremental Contact Model for Hyperelastic Solids Using an In Situ Optical Interferometric Technique

Zheng,

Jiang

2024

Lubricants

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An Incremental Contact Model for Hyperelastic Solids with Rough Surfaces

Jiang,

Liang

2023

Tribol Lett

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An incremental contact model for hyperelastic solids with rough surfaces

Jiang

Liang

2023

Preprint

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Hyperelastic materials like gels and rubbers have numerous applications in daily life and industrial production. However, most traditional contact models for rough solids do not include the hyperelastic deformation mechanism. This paper extends the linear-elastic incremental equivalent contact model to study the contact processes of hyperelastic rough solids. For any specific surface separation, the contact stiffness is determined by the total area and number of the contact patches, as well as the instantaneous tangent modulus. Analogous to buckle theory, we introduce the hyperelasticity of materials through employing the tangent modulus. By integrating the stiffness of contact spots, the normal contact force is then obtained. The load-area relation predicted by the present model exhibits consistency with finite element results even up to a contact area fraction of 90%. For hyperelastic solids with self-affine fractal rough surfaces, we investigate the effect of surface morphologies on contact behaviors. This research will be helpful for further studies about the lubrication, leakage, and wear of contact interfaces.

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Contact of Rough Surfaces: An Incremental Model Accounting for Strain Gradient Plasticity

Cited by 4 publications

References 41 publications

Experimental Investigation of an Incremental Contact Model for Hyperelastic Solids Using an In Situ Optical Interferometric Technique

Experimental Investigation of an Incremental Contact Model for Hyperelastic Solids Using an In Situ Optical Interferometric Technique

An Incremental Contact Model for Hyperelastic Solids with Rough Surfaces

An incremental contact model for hyperelastic solids with rough surfaces

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