ARTICLE
Experimental and numerical analysis of stick-slip suppression with the use of longitudinal tangential vibration
 
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West Pomeranian University of Technology, Faculty of Mechanical Engineering and Mechatronics, Szczecin, Poland
 
 
Submission date: 2019-08-13
 
 
Final revision date: 2019-10-30
 
 
Acceptance date: 2019-11-05
 
 
Online publication date: 2020-07-15
 
 
Publication date: 2020-07-15
 
 
Corresponding author
Marta Rybkiewicz   

Department of Mechanical Engineering and Mechatronics, West Pomeranian Uniwersity of Technology Szczecin, al. Piastów 19, 70-310, Szczecin, Poland
 
 
Journal of Theoretical and Applied Mechanics 2020;58(3):637-648
 
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ABSTRACT
The results of experimental tests and numerical simulation analyses of the possibility of partial reduction or entire elimination the stick-slip phenomenon in sliding motion through introduction of longitudinal tangential vibrations to the contact zone of a shifted body and the substrate are shown in the paper. The experimental tests were carried out on a specially designed stand. In the computational model, the dynamic equation of motion of the shifted body was used, and for the friction force description the LuGre model was adopted. A excellent consistency of the experimentally determined results with those calculated with the use of the developed model is obtained.
 
REFERENCES (28)
1.
Aarsnes U.J.F., Di Meglio F., Shor R.J., 2018, Avoiding stick slip vibrations in drilling through startup trajectory design, Journal of Process Control, 70, 24-35.
 
2.
Abdo J., Mahmoud T., Abouelsoud A., 2009, The effect of excitation frequencies on stickslip amplitude, 3rd International Conference on Integrity, Reliability and Failure, Porto, Portugal, 20-24 July.
 
3.
Abdo J., Tahat M., Abouelsoud A., Danish M., 2010, The effect of frequency of vibration and humidity on stick-slip amplitude, International Journal of Mechanics and Materials in Design, 6, 45-51.
 
4.
Abdo J., Zaier R., 2012, A novel pin-on-disk machine for stick-slip measurements, Materials and Manufacturing Processes, 27, 751-755.
 
5.
Åstrom K.J., Canudas de Wit C., 2008, Revisiting the LuGre friction model, IEEE Control Systems, 28, 6, 101-114.
 
6.
Broniec Z., Lenkiewicz W., 1982, Static friction process under dynamic loads and vibration, Wear, 80, 261-271.
 
7.
Canudas de Wit C., Olsson H., Åstrom K.J, Lischinsky P., 1995, A new model for control of systems with friction, IEEE Transactions on Automatic Control, 40, 3, 419-425.
 
8.
Haessig D.A., Friedland B., 1991, On the modeling and simulation of friction, ASME Journal of Dynamic Systems, Measuremant and Control, 113, 3, 354-362.
 
9.
Jurczyński Ł., 2013, The use of high frequency forced vibrations for elimination of stick-slip phenomenon (in Polish), Master thesis, West Pomeranian Uniwersity of Technology, Szczecin.
 
10.
Kligerman Y., Varenberg M., 2014, Elimination of stick-slip motion in sliding of split or rough surface, Tribology Letters, 53, 2, 395-399.
 
11.
Krőger M., Neubauer M., Popp K., 2008, Experimental investigation on the avoidance of self-excited vibrations, Philosophical Transactions of the Royal Society A, 366, 1866, 785-810.
 
12.
Lenkiewicz W., 1969, The sliding friction process effect of external vibration, Wear, 13, 2, 99-108.
 
13.
Leus M., Abrahamowicz M., 2019, Experimental investigations of elimination the stick-slip phenomenon in the presence of longitudinal tangential vibration, ACTA Mechanica et Automatica, 13, 1, 45-50.
 
14.
Leus M., Gutowski P., 2009, The experimental analysis of the tangential stiffness of the flat contact joints (in Polish), Modelowanie Inżynierskie, 37, 185-192.
 
15.
Mfoumou G.S., Kenmoé G.D., Kofané T.C., 2019, Computational algorithms of time series for stick-slip dynamics and time-delayed feedback control of chaos for a class of discontinuous friction systems, Mechanical Systems and Signal Processing, 119, 399-419.
 
16.
Neubauer M., Neuber C.-C., Popp K., 2005, Control of stick-slip vibrations, Solid Mechanics nd its Applications, 130, 223-232.
 
17.
Olsson H., 1996, Control Systems with Friction, Lund.
 
18.
Popov V.L., Starcevic J., Filippov A.E., 2010, Influence of ultrasonic in-plane oscillations on static and sliding friction and intrinsic length scale of dry friction processes, Tribology Letters, 30, 1, 25-30.
 
19.
Popp K., Rudolph M., 2003, Avoidance of stick-slip motion by vibration control, Proceedings in Applied Mathematics and Mechanics, 3, 120-121.
 
20.
Popp K., Rudolph M., 2004, Vibration control to avoid stick-slip motion, Journal of Vibration and Control, 10, 1585-1600.
 
21.
Qiu H., Yang J., Butt S., 2018, Investigation on bit stick-slip vibration with random friction coefficients, Journal of Petroleum Science and Engineering, 164, 127-139.
 
22.
Rymuza Z., 1989, Sliding guides in small mechanisms and precision instruments – tribological issues (in Polish), Pomiary, Automatyka, Kontrola, 5.
 
23.
Rymuza Z., 1992, The stick-slip phenomenon (in Polish), Pomiary, Automatyka, Kontrola, 12, 290-295.
 
24.
Teidelt E., Starcevic J., Popov V.L., 2012, Influence of ultrasonic oscillation on static and sliding friction, Tribology Letters, 48, 1, 51-62.
 
25.
Tolstoi D.M., 1967, Significance of the normal degree of freedom and natural normal vibrations in contact friction, Wear, 10, 199-213.
 
26.
Tolstoi D.M., Borisova G.A., Griegorova S.R., 1973, Friction reduction by perpendicular oscillation, Doklady Technical Physis, 17, 9, 907-909.
 
27.
Zhu X., Tang L., Yang Q., 2014, A literature review of approaches for stick-slip vibration suppression in oilwell drillstring, Advances in Mechanical Engineering, 967952, 1-17.
 
28.
Zuleeg J., 2015, How to measure, prevent, and eliminate stick-slip and noise generation with lubricants, SAE Technical Paper, 2015-01-2259, 1-7.
 
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