Abstract
Nowadays it is commonly considered that high damping materials which have both the good mechanical properties as structural materials and the high damping capacity for vibration damping are the most direct vibration damping solution. In metals and alloys however, exhibiting simultaneously high damping capacity and good mechanical properties has been noted to be normally incompatible because the microscopic mechanisms responsible for internal friction (namely damping capacity) are dependent upon the parameters that control mechanical strength. To achieve a compromise, one of the most important methods is to develop two-phase composites, in which each phase plays a specific role: damping or mechanical strength. In this review, we have summarized the development of the design concept of high damping composite materials and the investigation of their fabrication and properties, including mechanical and damping properties, and suggested a new design concept of high damping composite materials where the hard ceramic additives exhibit high damping capacity at room temperature owing to the stress-induced reorientation of high density point defects in the ceramic phases and the high damping capacity of the composite comes mainly from the ceramic phases.
Highlights
The damping capacity of a material is an evaluation of the energy dissipated in the material during mechanical vibration
There is not much analytical and experimental work reported on the effect of nano-scaled reinforcements on the damping capacity of Kireitseu et al [48] demonstrated that carbon nanotubes (CNT) employed to reinforce Metal matrix composites (MMCs) were able to enhance structural damping as well as composite stiffness
Through microstructure optimization and the fabrication route adjustment, high strength (>500 MPa) and high damping capacity (Q-1>0.03) composite materials could be realized with this novel design concept of MMCs
Summary
The damping capacity of a material is an evaluation of the energy dissipated in the material during mechanical vibration. Practical applications need low density materials that simultaneously exhibit a high damping capacity and good mechanical properties. In metals these properties are often incompatible, due to the dependence of the microscopic mechanisms involved in strengthening and damping. It would be of interest to develop new materials that simultaneously exhibit good mechanical properties and high damping [3,5] This is possible only when the microscopic mechanisms responsible for dissipation of the vibration energy are independent of that of the hardening and strengthening. Such a compromise can be achieved by the development of two-phase composites, in which each phase plays a specific role: damping or providing mechanical strength. A new design concept of high damping composite materials is suggested
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
