INFLUENCE OF THE NORMAL FORCE ON THE SLIDING FRICTION UNDER ULTRASONIC OSCILLATIONS

Natalie Milahin, Qiang Li, Jasminka Starcevic

DOI Number
-
First page
27
Last page
32

Abstract


The paper is devoted to an experimental investigation of the sliding friction force between a rapidly oscillating sample and a rotating steel plate. The sliding friction force is studied experimentally as a function of the oscillating amplitude, the sliding velocity and the normal force. The results have proved the hypothesis that the coefficient of friction is a function of dimensionless oscillation amplitude and dimensionless velocity.


Full Text:

PDF

References


Siegert, K., Ulmer, J., 2001, Superimposing Ultrasonic Waves on the Dies in Tube and Wire Drawing, Journal of Engineering Materials and Technology, 123(4), pp. 517-523.

Murakawa, M., 2001, The utility of radially and ultrasonically vibrated dies in the wire drawing process, J. Mater. Process. Technol. 113(1-3), pp. 81–86.

Ashida, Y., Aoyama, H., 2007, Press forming using ultrasonic vibration, J. Mater, Process. Technol. 187–188, pp. 118–122.

Siegert, K., Ulmer, J., 2001, Influencing the friction in metal forming process by superimposing ultrasonic waves, Annals of CIRP, 50 (1) , pp. 195–200.

Egashira, K.,Mizutani, K, 2002, Ultrasonic vibration drilling of microholes in glass, Annals of CIRP, 51 (1), pp. 339–342.

Littmann, W., Storck, H., Wallaschek, J., 2001, Sliding friction in the presence of ultrasonic oscillations: superposition of longitudinal oscillations, Arch. Appl. Mech. 71, pp. 549–554.

Tsai, C.C., Tseng, C.H., 2005, The effect of friction reduction in the presence of in-plane vibrations, Arch of Appl Mech 75, 164–176.

Chowdhury, M., Helali, M., 2006, The effect of frequency of vibration and humidity on the coefficient of friction, Tribol. Int. 39, 958–962.

Kumar, V.C., Hutchings, I.M., 2004, Reduction of the sliding friction of metals by the application of longitudinal or transverse ultrasonic vibration, Tribology International, 37(10), pp. 833-840.

Teidelt, E., Starcevic, J., Popov, V.L., 2012, Influence of ultrasonic oscillation on static and sliding friction, Tribology Letters, 48, pp 51-62.

Godfrey, D., 1967, Vibration reduces metal to metal contact and causes an apparent reduction in friction, Tribol. Trans. 10, pp 183–192.

Lenkiewicz, W., 1969, The sliding friction process: effect of external vibrations, Wear 13, pp 99–108.

Weishaupt, W., 1976, Reibungsverminderung durch mechanische Schwingungen, Technisches Messen 11, pp 345–348

Goto, H., Ashida, M., Terauchi, Y., 1984, Effects of ultrasonic vibration on the wear characteristics of a carbon steel: analysis of the wear mechanism, Wear 94, pp 13–27.

Thomsen, J., 1999, Using fast vibrations to quench friction-induces oscillations, J. Sound Vib. 228, pp 1079–1102.

Milahin, N., Starcevic S., 2014, Influence of the normal force and contact geometry on the static force of friction of an oscillating sample, Physical Mesomechanics, 17(3), pp. 228-231.

Popov, V.L., Psakhie, S., Popov, M., 2014, On the Role of Scales in Elastomer Friction, International Conference on Physical Mesomechanics of Multilevel Systems, AIP Conf. Proc. 1623, pp. 507-510.

Pohrt, R., Popov, V.L., 2013, Contact stiffness of randomly rough surfaces, Scientific Reports, 3, 3293.

Pohrt, R., Popov, V.L., 2013, Contact Mechanics of Rough Spheres: Crossover from Fractal to Hertzian Behavior, Advances in Tribology, 974178.


Refbacks

  • There are currently no refbacks.


ISSN: 0354-2025 (Print)

ISSN: 2335-0164 (Online)

COBISS.SR-ID 98732551

ZDB-ID: 2766459-4