|کد مقاله||کد نشریه||سال انتشار||مقاله انگلیسی||ترجمه فارسی||نسخه تمام متن|
|4976750||1367675||2018||10 صفحه PDF||ندارد||دانلود کنید|
â¢A new type of damper, tuned particle damper (TPD), is first presented.â¢An equivalent model is proposed to characterize the dynamic behavior of TPD.â¢Dynamic characteristic of TPD is investigated by comparing with classical DVA and PD.â¢An phase diagram is employed to analyze the dynamic characteristic of TPD.â¢An interesting finding about the dynamic characteristic of DVA is presented.
To better suppress the structural vibration in the micro vibration and harsh environment, aÂ new typeÂ ofÂ damper, tuned particle damper (TPD), was designed by combining the advantage of classical dynamic vibration absorber (DVA) and particle damper (PD). An equivalent theoretical model was established to describe the dynamic behavior of a cantilever system treated with TPD. By means of a series of sine sweep tests, the dynamic characteristic of TPD under different excitation intensity was explored and the damping performance of TPD was investigated by comparing with classical DVA and PD with the same mass ratio. Experimental results show that with the increasing of excitation intensity TPD shows two different dynamic characteristics successively, i.e., PD-like and DVA-like. TPD shows a wider suppression frequency band than classical DVA and better practicability than PD in the micro vibration environment. Moreover, to characterize the dynamic characteristic of TPD, a simple evaluation of the equivalent dynamic mass and equivalent dynamic damping of the cantilever system treated with TPD was performed by fitting the experimental data to the presented theoretical model. Finally, based on the rheology behaviors of damping particles reported by the previous research results, an approximate phase diagram which shows the motion states of damping particles in TPD was employed to analyze the dynamic characteristic of TPD and several motion states of damping particles in TPD were presented via a high-speed camera.
Journal: Mechanical Systems and Signal Processing - Volume 99, 15 January 2018, Pages 219-228