A Nonlinear Damper with Dynamic Load and an Elastic Slit Membrane: Modeling and Interaction Analysis

• Published in: Applied sciences Vol. 14; no. 17; p. 7663
• Main Authors: Sadeghian, Mostafa, Pilkauskas, Kestutis, Palevicius, Paulius, Ragulskiene, Jurate, Janusas, Giedrius, Dorosevas, Viktoras, Palevicius, Arvydas
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.09.2024
• Subjects: Construction; damper; Earthquakes; Energy; Fluids; membrane; nonlinear; Seismic engineering; Shock absorbers; Simulation; slit; Velocity; Viscosity; viscous
• ISSN: 2076-3417; 2076-3417
• DOI: 10.3390/app14177663

This article presents research into the feasibility of applying a nonlinear damper of a new conceptual structure. The key component of the damper is a circular membrane with slits that can move in a cylinder filled with viscous fluid. When an external load is applied to the damper, the membrane deforms, opening the slits. The flow of viscous fluid through the slits generates a damping force. The phenomenological model of the damper is based on the notion that the slit membrane moves according to the fundamental axisymmetric vibration mode of a circular membrane. The slit membrane blocks the entire radius of the pipe in the state of equilibrium when all slits are closed. As the membrane moves, the opening area of the slits varies depending on its deformation. This gives a nonlinear damping characteristic. The damping constant depends on the input displacement and velocity, which is the reason for the nonlinearity of the damping characteristic. From the phenomenological model, the nonlinear characteristic of the drag force is obtained. The performance of the damper is simulated using a mass–spring–damper system. Two cases of harmonic excitation and impulse excitation are analyzed. The results show that, using the slit membrane damper, the suppression of dynamic loads is more effective compared to a conventional linear damper.