Viscous damping
In continuum mechanics, viscous damping is a formulation of the damping phenomena, in which the source of damping force is modeled as a function of the volume, shape, and velocity of an object traversing through a real fluid with viscosity.[1]
Typical examples of viscous damping in mechanical systems include:
- Fluid films between surfaces
- Fluid flow around a piston in a cylinder
- Fluid flow through an orifice
- Fluid flow within a journal bearing
Viscous damping also refers to damping devices. Most often they damp motion by providing a force or torque opposing motion proportional to the velocity. This may be affected by fluid flow or motion of magnetic structures. The intended effect is to bring the damping ratio closer to 1.
Practical examples include:
- Shock absorbers in cars
- Seismic retrofitting with viscous dampers[2]
- Deployment actuators in spacecraft
Single-degree-of-freedom system
[edit]In a single-degree-of-freedom system, viscous damping models the relatitionship between force and velocity as shown below:
Where is the viscous damping coefficient with SI units of . This model adequately describes the damping force on a body that is moving at a moderate speed through a fluid.[3] It is also the most common modeling choice for damping.[4]
See also
[edit]References
[edit]- ^ Mechanical Vibrations, Rao, 5th ed.
- ^ Pollini, Nicolò; Lavan, Oren; Amir, Oded (2017). "Minimum-cost optimization of nonlinear fluid viscous dampers and their supporting members for seismic retrofitting". Earthquake Engineering & Structural Dynamics. 46 (12): 1941–1961. doi:10.1002/eqe.2888. ISSN 1096-9845. S2CID 114445524.
- ^ Tony L. Schmitz, K. Scott Smith. Mechanical Vibrations: Modeling and Measurement (2e). 2021. pp. 30, 51.
- ^ Tony L. Schmitz, K. Scott Smith. Mechanical Vibrations: Modeling and Measurement (2e). 2021. p. 52.