A predictive technique for evaluating structural vibration gain of damped suspensions in hard disk drives

The problem of resonant vibration of suspensions used in hard disk drives has been the subject of ongoing research. This study focuses on implementation of a finite element modeling methodology to predict the response for a suspension that includes an added damping component, either as a traditional constraint layer damper or as a design tool. High gains in suspensions result in off-track of the slider, which is the mechanism for reading and writing data. Analytical methodology uses the concept of modal strain energy to predict the modal damping of the structure at each resonant mode. Loss factors and strain energies of each material used in the structure quantify the amount of modal damping at a particular mode. Development of the methodology allows optimization studies of standard damping applications, such as a constraint layer damper. In addition, the methodology enables FEA as a design tool to develop innovative solutions for improved efficiency and higher performance.