The objective of this study is to explore the developement mechanical characteristics of the low-capacity fluid dampers through our cooperation with company with possible industrial applications in control of machine-induced vibration, and earthquake resistance of building structure (on both wood and steel model structures) . To get more insight of the mechanics of viscous fluid dampers, a fluid dynamic model has been developed based on theories in fluid dynamics with consideration of non-Newtonian fluid. The effects of piston area, piston thickness and gap of the annular orifice on the mechanical behavior of the fluid dampers are assessed via the parametric study. Both the damping coefficient and stiffness of the fluid damper are found to be frequency- dependent, which could not be reflected by using the Kelvin’s model. Results of the component tests indicate that the fluid dampers developed by cooperation with company exhibit rich and stable energy-dissipative characteristics superior to those of the prototype by the Japan manufacturer. Effectiveness of the low-capacity fluid dampers in machine-induced vibration control have been observed via the simulation tests. The dampers are proved to be effective in a wide range of spectrum as revealed from the one-third octave spectrum analysis, and generally speaking, the control effect is most prominent within the bandwidth of 30~100 Hz. A series of seismic performance tests of the fluid dampers for structural response control by the shaking table has been conducted. Experimental results for both the wood and steel model structures show that the fluid dampers are effective in seismic vibration control. The potential of using fluid dampers for earthquake protection of building structures has been confirmed.