Vibration Reduction with Rubber-Metal Cab Supports

Alujević, N., Čakmak, D., Wolf, H. & Jokić, M. (2018). Passive and active vibration isolation systems using inerter. Journal of Sound and Vibration, 418, 163-183. Search in Google Scholar

Au-Yeung, K.Y., Yang, B., Sun, L., Bai, K. & Yang, Z. (2019). Super damping of mechanical vibrations, Scientific Reports, 9, 17793-2019. Search in Google Scholar

Avdonin, V.D. (2015). Vibration-absorbing composite coatings. Thesis for the degree of candidate of technical sciences. Saransk, 123 p. Search in Google Scholar

Bashmur K.A., Petrovsky E.A., Mazurov I.A., Bukhtoyarov, V.V., Tynchenko, S.V. & Gorodov, A.A. (2019). Adaptive vibration absorbing method of torsional vibrations for processing equipment. Journal of Physics: Conference Series, 1353. Search in Google Scholar

Carpineto, N., Lacarbonara, W. & Vestroni, F. (2014). Hysteretic Tuned Mass Dampers For Structural vibration mitigation, Journal of Sound and Vibration, 333, 1302-1318. Search in Google Scholar

Hao R. B., Lu Z. Q., Ding H. & Chen L. Q. (2022). A nonlinear vibration isolator supported on a flexible plate: analysis and experiment. Nonlinear Dynamics. Search in Google Scholar

Hazra S. & Ghosh M. (2009). Vibration Isolation Performance of a Vehicle Suspension System Using Dual Dynamic Dampers. Advances in Vibration Engineering, 8(2), 193-200. Search in Google Scholar

Hegazy S., Rahnejat H. & Hussain K. (2000). Multi-body dynamics in full-vehicle handling analysis under transient manoeuvre. Vehicle System Dynamics, 34(1), 1-24. Search in Google Scholar

Jakubczyk-Gałczyńska A., Jankowski R. (2014). Trafficinduced vibrations. The impact on buildings and people. The 9th International Conference “Environmental Engineering 2014”, May 22-23, 2014, Vilnius, Lithuania. Search in Google Scholar

Kirkham E.E. (1997). Machine tool vibration isolation system. The Journal of the Acoustical Society of America, 101(6), 1-10. Search in Google Scholar

Klukin I.I. & Borba S. (1971). Shumom na traktorakh. Minsk: Nauka i technika, 416. Search in Google Scholar

Kobzev K.O. (2016). Obosnovaniye parametrov sistemy snizheniya vibratsii na rabochem meste operatora kozlovykh kranov. Internet zhurnal Naukovedeniye, 8(5), 1-7. Search in Google Scholar

Kurbonov SH.KH. & Sulaymanov S.S. (2022). Raschot zashchitnykh sredstv, obosnovaniye skhemy zvuko-vibroizoliruyushchikh kabiny. Universum: tekhnicheskiye nauki: elektron. nauchn. zhurn. 2(95). Search in Google Scholar

Razumovsky M.A. (1973). Bo’ba s shumom na traktorakh. Minsk: Nauka i Tekhnika, 208. Search in Google Scholar

Seidel H. & Heide R. (1986). Long-term effects of whole-body vibration: a critical survey of the literature. International Archives of Occupational and Environmental Health, 58(1), 1-26. Search in Google Scholar

Serridge M. & Torben R. (1987). Licht. Theory and application handbook. Piezoelectric accelerometer and vibration preamplifiers. Bruel & Kjaer, 150. Search in Google Scholar

Swanson D.A., Norris M.A. (1994). Multidimensional mount effectiveness for vibration isolation. Journal of Aircraft, 31(1), 188-196. Search in Google Scholar

Vasil’yev A.V. (2004). Raschet i snizheniye vnutrennego shuma i vibratsii avtomobiley. Izvestiya Samarskogo nauchnogo tsentra rossiyskoy akademii nauk, 4(2), 390-398. Search in Google Scholar

Wang H.J. & Chen, L.W. (2002). Vibration and damping analysis of a three-layered composite annular plate with a viscoelastic mid-layer. Composite Structures, 58(4), 563-570. Search in Google Scholar

Wang, L.Y., Zhao, Y., Li, L.P. & Ding, Z.Y. (2016). Research on the vibration characteristics of the commercial-vehicle cabin based on experimental design and genetic algorithm. Journal of Vibroengineering, 18(7), 4664-4677. Search in Google Scholar