Since 1963
COMMUNICATION
Concept of an adaptive-tuned particles impact damper
1
Warsaw University of Technology, Institute of Machine Design Fundamentals, Warsaw, Poland
Submission date: 2019-08-26
Final revision date: 2019-12-02
Acceptance date: 2020-01-07
Online publication date: 2020-07-15
Publication date: 2020-07-15
Journal of Theoretical and Applied Mechanics 2020;58(3):811-816
KEYWORDS
TOPICS
ABSTRACT
The most popular devices for attenuation of mechanical vibrations are dampers or shock
absorbers. Two main energy dissipation strategies can be generally distinguished: passive
and active (semi-active). Passive vibration isolation methods are the most commonly used,
mainly because of their simplicity and low maintenance costs. Among passive vibration
attenuation techniques, also Particle Impact Dampers (PID) are involved. Classical PID
solutions have some certain limitations. This paper aims at presenting the new concept of
an adaptive tuned PID damper that can pretend to be placed among semi-active energy
dissipation methods.
REFERENCES (12)
1.
Bartkowski P., Zalewski R., Chodkiewicz P., 2019, Parameter identification of Bouc-Wen model for vacuum packed particles based on genetic algorithm, Archives Of Civil And Mechanical Engineering, 19, 322-333.
2.
Chen J., Georgakis C. T., 2013, Tuned rolling-ball dampers for vibration control in wind turbines, Journal of Sound and Vibration, 332, 5271-5282.
3.
Du Y., 2017, A spring-supported fine particle impact damper to reduce harmonic vibration of cantilever beam, Advances in Mechanical Engineering, 9, 5, 1687-8140.
4.
Du Y., Wang S., 2010, Modeling the fine particle impact damper, International Journal of Mechanical Sciences, 52, 1015-1022.
5.
Fitzgerald B., Sarkar S., Staino A., 2018, Improved reliability of wind turbine towers with active tuned mass dampers (ATMDs), Journal of Sound and Vibration, 419, 103-122.
6.
Hussan M., Rahman M.S., Sharmin F., Kim D., Do J., 2018, Multiple tuned mass damper for multi-mode vibration reduction of offshore wind turbine under seismic excitation, Ocean Engineering, 160, 449-460.
7.
Lei X., Wu C., Chen P., 2018, Optimizing parameter of particle damping based on Leidenfrost effect of particle flows, Mechanical Systems and Signal Processing, 104, 60-71.
8.
Paget A.L., 1937, Vibration in steam turbine buckets and damping by impacts, Engineering, 143, 305-307.
9.
Snoun C., Trigui M., 2018, Design parameters optimization of a particles impact damper, International Journal on Interactive Design and Manufacturing (IJIDeM), 12, 1283-1297.
10.
Zalewski R., Żurawski M., Chodkiewicz P., 2019, Passive-adaptive vibration damper with loose grain material (in Polish), Patent P.430075.
11.
Zhang K., Chen T., Wang X., Fang J., 2016, Rheology behavior and optimal damping effect of granular particles in a non-obstructive particle damper, Journal of Sound and Vibration, 364, 30-43.
12.
Zhang Z., Staino A., Basu B., Nielsen S.R., 2016, Performance evaluation of full-scale tuned liquid dampers (TLDs) for vibration control of large wind turbines using real-time hybrid testing, Engineering Structures, 126, 417-431.
Share
| eISSN: | 2543-6309 |
| ISSN: | 1429-2955 |
We process personal data collected when visiting the website. The function of obtaining information about users and their behavior is carried out by voluntarily entered information in forms and saving cookies in end devices. Data, including cookies, are used to provide services, improve the user experience and to analyze the traffic in accordance with the Privacy policy. Data are also collected and processed by Google Analytics tool (more).
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
