A Leakage Model of Contact Mechanical Seals Based on the Fractal Theory of Porous Medium

A theoretical model for calculating the leakage rate of contact mechanical seals based on the fractal theory of the porous media, which can consider the real seal contact interface and objectively reflect the flow of the interfacial fluid from a microscopic perspective, is established. In order to obtain the microstructural parameters of the porous media included in the leakage model, such as the fractal dimension and the maximum pore diameter, the real seal contact interface obtained from experiments is reconstructed, a contact model between the dynamic and static rings is proposed, and then the calculation methods for the interface characteristic parameters are provided. Numerical simulation results show that as the contact pressure increases from 0.05 to 0.5 MPa, the interface porosity and the maximum pore diameter decreases gradually. Furthermore, the fractal dimension of the pore area increases and the leakage rate of the interface decreases from 0.48 to 0.33 mL/h. The proposed method provides a novel way of calculating the leakage rate of contact mechanical seals.

Automated summary

A theoretical model based on the fractal theory of porous media was established for calculating the leakage rate of contact mechanical seals, considering the real seal contact interface and providing calculation methods for interface characteristic parameters. Numerical simulation results showed that as contact pressure increased, interface porosity and maximum pore diameter decreased gradually, leading to a decrease in leakage rate.