Simplified Calculation Model for Contact Resistance Based on Fractal Rough Surfaces Method

Electrical contact resistance (ECR) is critical to evaluate the stability and reliability of electrical connections. In this paper, a simplified contact model is established for rough surfaces based on the fractal theory and Monte Carlo method, which can overcome the difficulty of constructing the resistance networks for traditional contact models. The model reveals the influence of fractal parameters D and G on the surface morphology and contact characteristics. The established surface method can simulate Gaussian and non-Gaussian isotropic surfaces. Then the contact resistance considering a contaminated film is calculated, which provides a quantitative analysis of the change and the influencing factors. The accuracy of the calculation method in this paper is ensured by comparing the existing experimental data and finite element results. The results show that the contact surface with D of 1.5 has the largest real contact area and the smallest contact resistance. The model has accurate calculation results when dimensionless contact load F* is less than 4 x 10(-3).

Automated summary

In this paper, a simplified contact model based on fractal theory and Monte Carlo method is established to simulate the electrical contact resistance (ECR) of rough surfaces. The model overcomes the difficulty of constructing resistance networks in traditional contact models and reveals the influence of fractal parameters on surface morphology and contact characteristics. The contact resistance considering a contaminated film is calculated, providing a quantitative analysis of the change and influencing factors. The accuracy of the method is validated by comparing with experimental data and finite element results. The results show that the model has accurate calculation results for dimensionless contact load below 4 x 10(-3).